EP1251769A1 - A method and system for pressure based measurements of cfr and additional clinical hemodynamic parameters - Google Patents
A method and system for pressure based measurements of cfr and additional clinical hemodynamic parametersInfo
- Publication number
- EP1251769A1 EP1251769A1 EP00909600A EP00909600A EP1251769A1 EP 1251769 A1 EP1251769 A1 EP 1251769A1 EP 00909600 A EP00909600 A EP 00909600A EP 00909600 A EP00909600 A EP 00909600A EP 1251769 A1 EP1251769 A1 EP 1251769A1
- Authority
- EP
- European Patent Office
- Prior art keywords
- pressure
- sensor
- obstruction
- stenosis
- flow reserve
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn
Links
Classifications
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/68—Arrangements of detecting, measuring or recording means, e.g. sensors, in relation to patient
- A61B5/6846—Arrangements of detecting, measuring or recording means, e.g. sensors, in relation to patient specially adapted to be brought in contact with an internal body part, i.e. invasive
- A61B5/6847—Arrangements of detecting, measuring or recording means, e.g. sensors, in relation to patient specially adapted to be brought in contact with an internal body part, i.e. invasive mounted on an invasive device
- A61B5/6851—Guide wires
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/02—Detecting, measuring or recording pulse, heart rate, blood pressure or blood flow; Combined pulse/heart-rate/blood pressure determination; Evaluating a cardiovascular condition not otherwise provided for, e.g. using combinations of techniques provided for in this group with electrocardiography or electroauscultation; Heart catheters for measuring blood pressure
- A61B5/021—Measuring pressure in heart or blood vessels
- A61B5/0215—Measuring pressure in heart or blood vessels by means inserted into the body
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/02—Detecting, measuring or recording pulse, heart rate, blood pressure or blood flow; Combined pulse/heart-rate/blood pressure determination; Evaluating a cardiovascular condition not otherwise provided for, e.g. using combinations of techniques provided for in this group with electrocardiography or electroauscultation; Heart catheters for measuring blood pressure
- A61B5/026—Measuring blood flow
Definitions
- Vascular diseases are often manifested by reduced blood flow due to atherosclerotic occlusion of vessels
- occlusion of the coronary arteries supplying blood to the heart muscle is a major cause of heart disease
- Numerous methods are currently available for treating various lesion types Some of these methods are given herein below, sequenced from softer to heavier, relating to their ability to open calcified lesions, per cutaneous transluminal angioplasty (PTCA), Cutting balloon angioplasty, directional coronary atherectomy (DCA), rotational coronary atherectomy (RCA), Ultrasonic breaking catheter angioplasty, transluminal extraction catheter (TEC) atherectomy Rotablator atherectomy, and excimer laser angioplasty (ELCA )
- PTCA cutaneous transluminal angioplasty
- DCA directional coronary atherectomy
- RCA rotational coronary atherectomy
- Ultrasonic breaking catheter angioplasty transluminal extraction catheter
- TEC transluminal extraction catheter
- Rotablator atherectomy and exci
- Lesion geometry is evaluated by angiography, qualitative coronary angiography (QCA), or by intravascular ultrasound (IVUS) These measurements allow calculation of the percent diameter stenosis (angiography or QCA) or percent area stenosis (IVUS) This information is used to estimate stenosis severity, but during the last years clinicians have realized that direct physical information about pressure and flow is necessary for complete evaluation of coronary artery disease Physiological measurements such as pressure gradient have been clinically used as an indicator for lesion severity However, previous attempts to relate the pressure gradient across the stenosis to its functional significance have been disappointing The decrease in the pressure gradient after PTCA has been used to assess the success of the treatment, with poor correlation.
- the coronary flow velocity reserve (CFVR) is defined as the ratio of hyperemic to baseline flow velocity
- the fractional flow reserve (FFR) is defined as the ratio of distal (to stenosis) pressure (Pd) to aortic pressure (Pa) during hyperemia
- Pd distal
- Pa aortic pressure
- Hyperemic conditions are obtained by administration of vasodilators (e g papave ⁇ ne, adenosine)
- vasodilators e g papave ⁇ ne, adenosine
- Clinical studies have demonstrated that in most cases, lesions with CFVR ⁇ 2 must be treated using one of the above mentioned methods, whereas for patients with CFVR > 2, angioplasty may be avoided Similarly, in most cases angioplasty may be avoided if FFR > 0 75 Coronary flow occurs essentially during diastole while systolic contribution to total coronary flow is smaller
- the FFR and CFVR are independent but complementary indicators The first characterize the specific lesion whereas the second is a more global parameter, characterizing the lesioned vessel (lesion and distal bed)
- Clinical studies show that for approximately 75% of the patients CFR and FFR lead to the same conclusion regarding the lesion significance At the same time, for 25% of the patients, the conclusions regarding lesion significance were different This means that simultaneous determination of coronary flow reserve and fractional flow reserve is highly important and gives the clinician the additional and more complete information regarding the lesion severity
- This invention provides a method for calculating the flow-based clinical characteristics, coronary flow reserve (CFR) and diasto c to systolic velocity ratio (DSVR), in addition to the FFR, using pressure measurements across a stenosis
- CFR 0 coronary flow reserve in the same vessel without stenosis
- DSVR diasto c to systolic velocity ratio
- the present invention relates generally to a sensor apparatus for determination of characteristics in a tubular conduit, such as a blood vessel or the urethra, having at least one pressure sensor adapted to measure pressure across an obstruction
- This invention provides, a processor unit operatively connected to the at least one sensor, and a program for controlling the processor unit
- the processor unit is operative with the program to receive signals from the sensor, identify changes in the sensor signal, detect characteristics of the tubular conduit, the characteristics of the tubular conduit being derived from changes in the sensor signal, and recognize and assign a label to the characteristic of said tubular conduit
- This invention provides a system which includes the Automatic Similar Transmission method
- the characteristics that may be determined include a flow ratio in a blood vessel, a coronary flow reserve in a blood vessel diastole to systole velocity ratio in a blood vessel, coronary flow reserve together with fractional flow reserve in the same blood vessel without stenosis and analysis of their correlation for estimation of vascular bed conditions, coronary flow reserve together with fractional flow reserve in the same blood vessel without stenosis for estimation of vasodilatation effectiveness
- this invention provides the determination of a hemodynamic condition of the artery by determining the vascular bed index (VBI 0 ) which is equal to the ratio of mean shear to mean pressure
- VBI 0 vascular bed index
- the present invention provides a methods of determining/detecting microvascular disease due to the abnormal ratio of FFR to CFR based on either or proximal and/or distal pressure
- the method may be in combination with a balloon procedure
- the methods described provide for post PTCA evaluation (prior to stenting), determination or validation of dilatation success by subsequent CFR increase after PTCA, and indication of whether a stent is neded
- the methods and systems provided herein indicate high probability of microvascular disease, due to the abnormal ratio of FFR to CFR
- Post Stenting in combination with a deflated balloon allows the estimation of CFR of the vessel
- only a distal pressure measurement will allow the CFR calculation
- this invention provides determining CFR and FFR directly from intraarterial pressure measurements, thus the simultaneous CFR and FFR measurements permit one to obtain additional information about the vascular bed
- the present invention provides the hemodynamical parameters in estimating the severity of stenotic blood vessels in an attempt to increase the reliability of these parameters
- Fig 1 is a schematic isometric view of a system for determining blood vessel hemodynamic parameters, constructed and operative in accordance with a preferred embodiment of the present invention
- Fig 1 a are schematics isometric view of a system for determining blood vessel hemodynamic parameters, constructed and operative in accordance with another preferred embodiment of the present invention
- Fig 1 b are schematics isometric view of a system for determining blood vessel hemodynamic parameters, constructed and operative in accordance with another preferred embodiment of the present invention
- Fig 2 is a schematic functional block diagram illustrating the details of the system 1 of Fig 1 ,
- Fig 2 a is a schematic functional block diagram illustrating the details of the system 1 a of Fig 1 a,
- Fig 3 is a schematic isometric view of a part of system 1 or 1 a of Fig 1 or 1 a, constructed and operative in accordance with another preferred embodiment of the present invention
- Fig 4 is a schematic isometric view of an in-vitro system, constructed and operative in accordance with a preferred embodiment of the present invention
- Fig 5 is a schematic detailed illustration of the in-vitro tubing system 51 of Fig 4
- Fig 6 is a detailed schematic illustration of the experimental section 44 of Fig 5 and the positioning of the pressure sensors within a the latex tube during the operation of the system of Figs 4 and 5
- Fig 7 is a schematic cross section illustrating an artery with a stenosis and points A and B designating pressure measurement points
- Fig 8 is a schematic cross section of a blood vessel, illustrating the positioning of the two pressure sensors used in Method 1
- Fig 9 is a schematic cross section of a blood vessel, illustrating the positioning of the pressure sensors used in Method 2
- Fig 10 presents an example of pressure data used by Method 3 to determined hemodynamic coefficients
- Fig 1 1 presents the result of the calculation performed on the data shown
- Fig 12 is a schematic cross section of a blood vessel, illustrating the positioning of the pressure sensors used in Method 3
- Fig 13 presents the positioning of pressure sensors and stenosis inside the latex test tube of the in-vitro system of Figs 4-6 This configuration was used to validate Method 1 , the transfer function method
- Fig 14 illustrates a calculated pressure pulse by Method 1 , with the actual pressure pulse measured at that point
- Fig 15 illustrates an artery with a stenosis, a fluid filled pressure catheter and a pressure wire
- Points A and B designate measurements points
- Fig 16 presents pressure and ECG data, measured on human at rest condition, used by Method 4
- Fig 17 presents the ECG signals, at rest, after time transformation The transformation is done using Method 2
- Fig 18 presents the fluid filled catheter pressure signals at rest and after synchronization of the pulses
- Fig 19 presents the synchronized pressure signals representing the pressure proximal and distal to the stenosis
- Fig 20 presents ECG and pressure signals measured at point A during rest and at point B during vasodilatation state
- Fig 21 presents ECG signals, at rest (point A) and during vasodilatation (point B), after synchronization, applying the transformation of Method 2
- Fig 22 presents the fluid filled catheter pressure signals, at rest (point A) and during vasodilatation (point B), after synchronization of the pulses
- Fig 23 presents the guide wire pressure signals, at rest (point A) and during vasodilatation (point B), after synchronization of the pulses
- Fig 24 presents the distribution of a set of synchronized and transformed pressure signals measured at rest and during vasodilatation, used for determining mean values of hemodynamic coefficients
- Fig 25 presents the calculated values of the non-dimensional flow using the data shown in Fig 24
- Fig 26 presents the calculated values of CFR and FFR for each pulse
- Fig 27 presents the mean values over number of heartbeats of pressure at point A and point B at rest and vasodilation conditions
- Fig 28 presents the calculated values of the non-dimensional flow using the data described in Fig 27
- Fig 29 presents human data of ECG signals and pressure measurements during rest and vasodilatation These data are used to calculate hemodynamic parameters using synchronization by ECG signals
- Fig 30 presents synchronized pressure signals during rest and vasodilatation
- Fig 31 presents non-dimensional flow curves calculated from the synchronized curves of Fig 30
- Fig 32 presents the mean values of the synchronized pressure signals shown in Fig 30
- Fig 33 presents the calculated mean non-dimensional flow used to determine hemodynamic parameters
- Fig 34 illustrates the positioning of the pressure sensors and measurements location when using the method of synchronization by max pressure signal
- Fig 35 illustrates the pressure measurement points inside a non-lesioned blood vessel
- Fig 36 illustrates a balloon artificial obstruction inside a non-lesioned blood vessel and pressure measurement distal to the balloon
- Fig 45 illustrating a cross section of an artery 30 having an arterial walll 32 and a stenosis 34 Two points A and D upstream and downstream of the stenosis define a section of the artery
- the hemodynamic parameter FFR, along this section, is of interest
- the pressure gradient in a blood vessel without stenosis is small (pressure difference between two points 5cm apart is less then 1 mm Hg)
- the accuracy of the devices for pressure measurement, which are used in medicine for intracoronary pressure measurements does not allow accurate determination of such small pressure differences Therefore, one cannot make an accurate calculation of flow using these existing pressure measurement devices in a healthy non-stenosed vessel
- the situation is different if an obstruction exists in the blood vessel (stenosis or some artificial obstruction)
- the pressure difference across such an obstruction may reach 40-50 mmHg at rest and 60-70 mmHg during hyperemia
- This significant pressure difference may be measured with high accuracy and may be used for calculations of coronary flow reserve (CFR), using the methods and system presented herein
- This calculated CFR might be slightly different then the coronary flow velocity reserve (CFVR) as measured by the Flow wire
- the difference may arise from changes in the velocity profiles Limiting to the available technologies, accurate results may be achieved if the pressure difference across the stenosis at rest is more then 4
- the present invention provides methods and a system for calculation of CFR and FFR from on line intra-art pressure measurements
- Intracoronary pressure measurements were made in patients undergoing diagnostic angiography with findings of lesions of questionable clinical significance (intermediate lesions of 50-70% visual stenoses severity)
- Basal pressure measurements proximal, distal and during trans-lesional pull back were made with the methods and systems provided herein
- Patients were given intracoronary adenosine to achieve maximal vasodilatation and measurements were taken
- K is a constant determined solely by the stenosis diameter
- the coronary flow reserve is defined as the ratio of the mean hyperemic flow to the mean flow at rest and may be calculated if the pressure difference across the stenosis is known during rest and hyperemia.
- the coronary flow reserve may be calculated if the pressure difference across the stenosis is known during rest and hyperemia.
- Equations (2) and (3) are valid only for short stenosis.
- the pressure difference across the stenosis may be expressed as (Young
- equations (2) and (3) may be used If ⁇ p across the stenosis is more then 4 mmHg, the accuracy of CFR calculation will reach (10%)
- CFR 0 is the coronary flow reserve of a healthy vascular bed without stenosis i o Using the following notations
- Q v mean flow over a heartbeat in a stenotic vessel during hyperemia
- Q N mean flow over a heartbeat in the same non-stenotic vessel at rest
- Q N V - mean flow over a heartbeat in the same non-stenotic vessel during hyperemia (vasodilatation)
- CFR and FFR are known, then the coronary flow reserve (CFRO) in the same vessel, in case of healthy vascular bed, may be derived
- CFR 0 indicates a non healthy vascular bed
- Too low value of CFR for given FFR indicates either downstream flow restriction (additional stenosis) or insufficient infusion of vasodilator
- Too high value of CFR for given FFR indicates vascular bed disease
- the last equation may be used for determination of coronary flow reserve by positioning an artificial obstruction in a blood vessel, as presented herein below
- calculating CFR and FFR may be accomplished by dividing into pulses the proximal and distal pressure Dividing the pulses are known to those skilled in the art For example, one use an ECG signal or only using a pressure signal
- the Automatic Similar Transformation (AST) Method the steps of which are described in Figure 43
- the systems provided herein include the AST method
- mean pressure pulse P mean ( ⁇ ) is calculated, using averaging over all pulses for a give ⁇
- Six pressure signals result mean proximal fluid filled pressure Fp( ⁇ ), mean proximal pressure, measured by pressure transducer Pp( ⁇ ), mean fluid filled pressure Fd( ⁇ ) and mean pressure transducer pressure Pd( ⁇ ) both measured at rest when pressure transducer is distal to stenosis mean fluid filled pressure Fv( ⁇ ) and mean pressure transducer pressure Pv( ⁇ ) both measured during vasolidation when pressure transducer is distal to stenosis
- Pressure signals Pd( ⁇ ) and Pv( ⁇ ) are corrected to the changes in aortic pressure
- step 5 The steps of step 5 applied to every n-th pulse P 3n (1200) remaining after stage 2 Then CFR n for this pulse is calculated using equation
- the mean velocity u may be calculated by Young&Tsai equation (without linear term)
- FFR can be used to estimate % stenosis
- Figs 1 , 1 a, 1 b 2 and 2 a present a schematic isometric view of a system for determining blood vessel (lesion regions and non-lesioned regions) clinical hemodynamic characteristics CFR , DSVR and FFR
- the system is constructed and operative in accordance with two embodiment of the present invention (1 and 1 a)
- Fig 2 and 2 a are schematic functional block diagrams illustrating the details of the system 1 of Fig 1 and i o system 1 a of Fig 1 a
- the systems 1 , 1 a, and 1 b include a pressure sensor catheter or guide wire 4 inserted into the vessel directly or via a catheter lumen 3 for measuring the pressure inside a blood vessel
- the lumen catheter may be a guiding catheter (e g 8F Archer coronary guiding catheter from Medtronic Interventional Vascular,
- any other hollow catheter System 1 and systems 1 a and 1 b may include one (4) or more (i e Fig 3) pressure sensors on guide wire and also a fluid filled (FF) pressure transducer 31
- the pressure sensor 4 can be the 3F one pressure sensor model SPC-330A or dual pressure catheter SPC-721 commercially available from Millar Instruments Ine , TX, U S A , or any other pressure catheter suitable for diagnostic 25 or combined diagnostic / treatment purposes such as the 0 014 guidewire mounted pressure sensor product number 12000 from Radi Medical Systems, Upsala, Sweden, or Cardiomet ⁇ cs WaveWire pressure guidewire from Cardiometrics Ine an Endsonics company of CA U S A
- the systems 1 , 1 a and 1 b also include a signal conditioner 23 such as a
- the signal conditioner 23 is suitably connected to the pressure sensor 4 for amplifying the signals of the pressure sensor
- the system 1 further includes an analog to digital (A/D) converter 28 (i e Nl E Series 5 Multifunction I/O model PCI-MIO-16XE-10 commercially available by National Instruments, Austin, TX) connected to the signal conditioner 23 and to the FF pressure transducer 31 for receiving the analog signals therefrom
- A/D analog to digital
- the signal conditioner 23 may be integrated in the data acquisition card of the computer 20, or may also be omitted altogether, depending on the specific type of pressure i o sensors used
- the system 1 a of Fig 1 a also includes a standard cardiac cathetenzation system 22, such as Nihon Kohden Model RMC-1 100, commercially available from Nihon Kohden Corporation, Tokyo, Japan
- the signal conditioner 23 and the FF pressure transducer 31 are directly connected to the monitoring system 22
- the signal conditioner 23 and the FF pressure transducer 31 are directly connected to the monitoring system 22
- the signal conditioner 23 and the FF pressure transducer 31 are directly connected to the monitoring system 22.
- the system 1 a further includes an analog to digital (A/D) converter 28 connected to the output of the monitoring system 22 through a shielded I/O connector box 27, such as Nl SCB-68 or BNC-2090 commercially available from National Instruments, Austin, TX
- the systems 1 and 1 a also include a signal analyzer 25 connected to the
- the signal analyzer 25 includes a computer 20 and optionally a display 21 connected to the computer 20 for displaying text numbers and graphs representing the results of the calculations performed by the computer 20 and a
- the A/D converter 28 can be a separate unit or can be integrated in a data acquisition card installed in the computer 20 (not shown)
- the computer 20 processes the pressure data, sensed by the pressure sensors 4 and acquired by the A/D converter 28 or the data acquisition card (not shown)
- the system 1 b includes a single hardware box 29 containing all signal conditioning, calculations, archiving options and digital display and output to a printer 26
- Fig 5 5 is a schematic diagram representing an in-vitro experimental apparatus constructed and operative for determining flow characteristics in simulated non-lesioned and lesioned blood vessels, in accordance with an embodiment of the present invention
- Fig 2 is a schematic functional block diagram illustrating the functional details of a system including the apparatus of Fig 5 and apparatus for i o data acquisition, analysis and display
- the fluidics system 51 of Fig 5 is a recirculating system for providing pulsatile flow
- the system 51 includes a pulsatile pump 42 (model 1421A pulsatile blood pump, commercially available from Harvard Apparatus, Ine , Ma, U S A )
- the pump 42 allows control over rate, stroke volume and systole / diastole ratio
- the pulsatile pump 42 allows control over rate, stroke volume and systole / diastole ratio
- the system 51 further includes a flexible tube 43 immersed in a water bath 44, to compensate for gravitational effects
- the flexible tube 43 is made from Latex and has a length of 120 cm
- the flexible tube 43 simulates an artery
- a bypass tube 45 allows flow control in the system and simulates flow partition between blood vessels
- a Windkessel compliance chamber 46 is located proximal to the flexible tube 43 to control the pressure signal characteristics
- the system 51 of Fig 5 further includes an artificial stenosis made of a tube section 55, inserted within the flexible tube 43
- the tube section 55 is made from a piece of Teflon tubing
- the internal diameter 52 (not shown) of the artificial stenosis 55 may be varied by using artificial stenosis sections fabricated separately and having various internal diameter
- Fig 6 is a schematic cross sectional view illustrating a part of the fluidics system 51 in detail
- Pressure is measured along 5 the flexible tube 43 using a pressure measurement system including MIKRO-TIP pressure catheters 57,58 and 59, SPC-320, SPC-721 or SPR-524 pressure catheter, connected to a model TCB-500 control unit, commercially available from Millar Instruments Ine , TX, U S A
- the catheters 57,58 and 59 are inserted into the flexible tube 43 via the connector 10, connected at the end of the flexible tube i o 43
- the catheters 57,58 and 59 include pressure sensors 24A, 24B and 24C, respectively, for pressure measurements
- a fluid filled pressure transducer 31 is connected to the system 51 via the end of the guiding catheter 3, inserted into the flexible tube 43 via the connector 9
- the fluid filled pressure transducer 31 is connected to the system 51 , when additional pressure readings are needed, or in
- the system 51 of Fig 5 also includes a flowmeter 1 1 connected distal to the flexible tube 43 and a flowmeter 12 connected to the bypass tube 45
- the flowmeters 1 1 and 12 are suitably connected to the A/D converter 28
- the flowmeters 1 1 and 12 are model 1 1 1 turbine flow meters, commercially available
- the system 41 includes the system 51
- the system 41 also includes a signal conditioner 23 of the type sold as model TCB-500 control unit commercially available from Millar Instruments
- the signal conditioner 23 is suitably connected to the pressure sensors 24A, 24B and/or 24C
- the system 41 further includes an analog to digital converter 28 (E series Instruments multifunction I/O board 28 model PC-MIO-16E-4, commercially available from National Ine , TX, U S A ) connected to the signal conditioner 23 for receiving the conditioned analog signals therefrom
- the system 41 also includes a signal analyzer 25 connected to the A/D converter
- the signal analyzer 25 includes a computer (Pentium 586) 20, a display 21 connected to the computer 20 for displaying text numbers and graphs representing the results of the calculations performed by the computer 20
- a printer 26 is suitably connected to the computer 20 for providing hard copy of the results for 5 documentation and archiving
- the computer 20 processes the pressure data which is sensed by the pressure sensors 24A, 24B and 24C and acquired by the A/D converter 28 and generates textual, numerical and graphic data that is displayed on the display 21
- the I/O board was controlled by a Labview graphical programming software, i o commercially available from National Instruments Ine , TX, U S A 10 sec interval of pressure and flow data were sampled at 5000Hz, displayed during the experiments on the monitor and stored on hard disk Analysis was performed offline using Matlab version 5 software, commercially available from The MathWorks, Ine , MA, U S A
- the system uses various methods to determine the hemodynamic parameters defined herein above CFR, DSVR, and FFR All the methods are based on measurement or calculation of the pressure gradient (pressure drop) between two points along a blood vessel or tubular conduit These two points may be located proximal and distal to a stenosis an aneurysm or a section of the vessel
- the artery 30 may also include a stenosis 34, obstructing the blood flow Points A and B are located proximal and distal to the stenosis
- the pressure over time, P A (t) and P B (t) enable the calculation of the above mentioned parameters
- CFR CALCULATION In order to estimate the CFR value, pressure measurements are performed with the patient in REST and HYPEREMIA conditions CFR parameter is calculated using the following equation
- the method of CFR calculation uses the pressure difference across the stenosis over a full heartbeat
- the methods provided herein provide for the calculation of CFR as the ration of the flow diastolic maximum during vasolidation and at rest (Figure 40)
- the ratio of flows during vasolidation and rest is almost constant during systole
- CFR may be calculated as a ratio of maximal flows at rest and during vasolidation
- the flow is proportional to the square root of the pressure difference across a stenosis, yielding the following equation
- diastole DSVR parameter is calculated by using the following equation
- FIG 8 illustrating a cross section of an artery 30 having an arterial wall 32 and stenosis 34
- Two points, A and B proximal and distal to the stenosis define a section of the artery
- the hemodynamic parameters CFR, DSVR, and FFR, along this section are of interest
- a guiding catheter 3 (or diagnostic catheter, or any other hollowed catheter) is inserted into the blood vessel of interest
- Both pressure sensors are connected to signal conditioners 23A and 23B, of the kind described in Figs 1 , 1 a and 2, 2 a
- Step 1 Simultaneous measurement of pressure is performed by the two pressure sensors, yielding Pr t) and Pr B (t) The measurement is performed while the patient
- Step 2 Simultaneous measurement of pressures is performed again, by the two pressure sensors, yielding Pv A (t) and Pv B (t) The measurement is performed while the patient is under the effect of vasodilation dragues
- FIG 9 illustrating a cross section of an artery 30 with an arterial wall 32 and a stenosis 34
- Two points A and B upstream and downstream of the stenosis define a section of the artery
- the hemodynamic parameters CFR, DSVR, and FFR, of this section are of interest
- a guiding catheter 3 (or diagnostic catheter, or any other hollowed catheter) is inserted into the blood vessel of interest
- the tip of the catheter is positioned at point A, at the proximal section of the vessel
- a pressure fluid filled transducer 31 is connected to the external end of the catheter (point C) and measures the pressure at that point
- a single guide wire (6) having a pressure sensor at its tip (4B) is inserted trough the guiding catheter and positioned so that the pressure sensor 4B is located at point B
- the pressure sensor is connected to a signal conditioner 23 as described in Figs 1 ,1 a and 2,2 a
- Step 1 Simultaneous measurement of pressure is performed by the two pressure sensors, yielding Pr c (t) and Pr B (t) The measurement is performed while the patient is at rest
- Step 2 Simultaneous measurement of the pressure is repeated, yielding Pv c (t) and Pv B (t) The measurement is performed while the patient is at vasodilatation condition
- P A is considered to be equal to P c , (P A ⁇ P C ) All 3 parameters (CFR, DSVR, and FFR) are calculated using the equations described herein above
- Fig 10 illustrating the data acquired on paper (velocity of 25 mm/sec)
- the data was digitized using a computer software
- Graph 61 illustrates pressure data versus time during rest Curves Per and Pbr describe the pressure at points C and B, respectively
- Graph 62 illustrates pressure data versus time during vasodilatation Curves Pcv and Pbv describe the pressure at points C and B, respectively Due to the high pressure gradient across the stenosis (more than 10 mmHg at rest condition), the pressure measured by the fluid filled manometer (Pc) may be used instead of pressure data at point A
- the system was run in two different modes to simulate rest and vasodilatation conditions These modes were obtained by changing three variables of the in-vitro system including the pump flow, the bypass opening and closure, and the height of the output reservoir Yielding various flow levels through the stenosis, with stable physiologic input pressure, simulating the aortic pressure Flowmeter 1 1 data and pressure data from both sensors were obtained in each system mode Applying the analysis described in Method 2 to this data yields the FFR and CFR values
- Fig 12 illustrating a cross section of an artery 30 having an arterial wall 32 and a stenosis 34
- Two points, A and B, proximal and distal to the stenosis define a section of the artery
- the parameters CFR, DSVR, and FFR of this section are of interest
- a guiding catheter 3 (or diagnostic catheter, or any other hollowed catheter) is inserted into the blood vessel of interest 30
- An external fluid filled pressure transducer 31 is connected to the guiding catheter ostium (proximal end), measuring the pressure at point C (referred as fluid field pressure)
- One guide wire 6, having a pressure sensor at its tip 4 is inserted through the guiding catheter and positioned so that the pressure sensor 4 is located at point
- the pressure sensor 4 is connected to system 23 described in Figs 1 , 1 a and 2, 2 a Then, the pressure sensor 4 is moved to point B for further measurements
- Step 1 The pressure sensor 4 is located proximal to the stenosis, at point A
- Step 2 Simultaneous measurement of pressure by the two pressure sensors, 4 and 31 are obtained, yielding Pr A (t) and Pr-(t)
- the measurements are performed while the patient is at rest
- the pressure sensor 4 is moved to point B, distal to the stenosis
- Step 3 Simultaneous measurement of pressure is performed by the two pressure sensors, 4 and 31 Data of pressure versus time Pr B (t) and Pr c (t) is obtained
- Step 4 Inducing vasodilatation
- Step 5 Simultaneous measurement of pressure is performed by pressure sensors 4 and 31 , yielding Pv B (t) and Pv c (t) The measurements are performed during vasodilatation condition
- Step 6 Pressure sensor 4 is moved backward to point A , proximal to stenosis
- Step 7 Simultaneous measurement of pressure is performed by the pressure sensors 4 and 31 , yielding Pv A (t) and Pv c (t) is obtained
- Step 3 Perform FAST FOURIER TRANSFORM (FFT) on X1 (t) and Y1 (t)
- Fx FFT(X1 )
- Fy FFT(Y1 )
- Tea Pr A 3 CONV (Tea, Pr c 3) i o
- the simultaneous pressure proximal and distal to the stenosis is known (Pr A 3 and Pr B 3)
- the same procedure is used to determine the simultaneous pressure, proximal and distal to the stenosis during vasodilatation (Pv A 5 and Pv B 5)
- the calculation of the parameters CFR, DSVR, and FFR is performed using the equation mentioned herein above
- the system included a Latex test tube with a smooth stenosis model, 2cm long, with an internal diameter of 2 mm
- the stenosis was located 35 8 cm from the left bath edge Cordis 8F MPA-I was located within the connector 9
- One pressure transducer was located along the latex tube
- Another pressure transducer was located within the guiding catheter to simulate 25 fluid filled pressure readings
- the graph designated 66 is the 5 calculated pressure at point P
- the graph designated 67 is the actual pressure measurement at point P, as measured by the sensor 24D during the same heartbeat Almost perfect match exists between the two curves (66 and 67)
- Optimal Overlap Method i o
- the idea of the Optimal Overlap method is based on the observation that fluid filled pressure wave pulse P c (t) is mathematically similar to P A (t) but a delayed version of the latter
- the best stretching coefficient ⁇ and the best delay ⁇ t, for which the function ⁇ P 2 (T + ⁇ t) is globally close to the foot of P A (t) is determined
- the reason for the appearance of the stretch coefficient is a possible change in
- i be the index of N successive samples in the foot of the same heart beat (that 20 is from onset of systole to, say 80%, of the maximum of the pressure wave P A (t)) and t the corresponding sample times
- Fig 12 illustrating a cross section of an artery 30 having an arterial wall 32 and a stenosis 34
- Two points A and B upstream and downstream of the stenosis define a section of the artery
- the hemodynamic parameters CFR, DSVR, and FFR, along this section are of interest
- a guiding catheter 3 (or diagnostic catheter) is inserted into the blood vessel of interest
- An external fluid filled pressure transducer 31 is connected to the guiding catheter entrance (proximal end) measuring the pressure at point C (fluid filled pressure)
- a guide wire 6 having a pressure sensor at its tip 4 is inserted through the guiding catheter and positioned so that the pressure sensor 4 is located at point A downstream the stenosis
- Both pressure sensors 4 and 31 are connected to the system 23 described in Fig 1 ,1 a and 2,2 a
- Step 1 Simultaneous pressure and ECG measurements are performed Pressure are measured by two pressure sensors 4 and 31 Data of pressure versus time Pr A (t) and Pr c (t) and ECG are acquired, while the patient is at rest condition Step 2 Pressure sensor 4 is moved to point B, distal to stenosis Step 3 Simultaneous measurements of pressure and ECG are repeated, yielding data of pressure versus time Pr B (t) and Pr r (t) and ECG Step 4 Induce vasodilatation
- Step 5 Simultaneous measurement of ECG and pressure is repeated yielding data of pressure versus time Pv B (t) and Pv c (t), and ECG The measurements are performed while the patient is at vasodilatation condition Step 6 (optional) Pressure sensor 4 is pulled back to point A proximal to stenosis while simultaneous measurements of pressure and ECG are performed Data of pressure versus time Pv A (t) and Pv c (t) and ECG chart are obtained
- FIG 15 Aortic pressure was measured with a fluid filled manometer (not shown) connected to the guiding catheter 93 Pressure in the LAD artery was measured using a Radi pressure wire 91 at point A upstream of the stenosis 92 Then, the pressure wire 91 was moved to measure the pressure at point B downstream of the stenosis Measurements at point A were made during rest, and at point B and C, during rest and during intracoronary adenosine injection (vasodilatation condition) Pressure signals from the fluid filled manometer, Radi guidewire pressure sensor 91 and ECG were simultaneously recorded and stored with sampling rate of 1 kHz
- the Optimal Method is used to move the section assigned 76-76a of the 5 ECG signal 76 (measured when pressure sensor 91 is at point B) to the section 75-75a of the ECG signal 75 (measured when Radi pressure wire is at point A)
- Linear time transformation is applied to the signal 76, in order to match the time length of the signals 75-75a and 76-76a
- Fig 17 where the Curve 76t is the transformed ECG curve 76 i o
- the same time transformation (moving and stretching) is applied to the data measured by the fluid filled pressure transducer and Radi pressure wire
- Figs 18 and 19 Fig 18 illustrates the measured fluid filled pressure, curve 71
- Fig 19 describes the measured pressure at point A, curve 72, and the
- the mean values, as measured by the fluid filled manometer when Radi pressure wire is at point A or B are different
- the pressure measured at point B by Radi pressure wire is corrected according to the observed difference of the mean fluid filled pressure signals
- the mean pressure correction turns the
- Fig 20 illustrating the pressure and ECG signals corresponding to vasodilatation condition
- Curve 81 is the fluid filled pressure
- Curve 82 is the Radi pressure
- the suggested method of FFR calculation is more accurate then the standard method due to the fact that pressure data at point A is used instead of pressure data measured by fluid filled manometer
- Fig 24 illustrates synchronized and transformed pressure data at point A during rest (curves set 90), at point B during rest (curves set 91 ) and at point B during vasodilatation (curves set 92)
- Fig 25 illustrates the derived non-dimensional flow during rest (curves set 94) and during vasodilatation (curves set 93)
- the example is based on human pressure data measured in the LAD artery, using a standard fluid filled pressure transducer, Radi pressure wire by Radi Medical Systems AB, Uppsala, Sweden and doppler flow wire by Endosonics Data of ECG, pressures measured by Radi guide wire and fluid filled manometer were 5 recorded and printed simultaneously These data were scanned and digitized for computerized analysis Some fragments of the digitized pressure and ECG curves, are shown on Fig 29
- the graph designated 106 describes pressure and ECG curves measured at rest while the Radi pressure sensor is located proximal to the stenosis (point A) i o
- the graph designated 107 describes pressure and ECG curves measured at rest while the Radi pressure sensor is located distal to the stenosis (point B)
- the graph designated 108 describes pressure and ECG curves measured during vasodilatation while the Radi pressure sensor is located distal to the stenosis (point B)
- Curve 101 in graphs 106, 107, 108 illustrate
- Fig 30 illustrates three sets of pressure signals after ECG synchronization 1 Curves set 109 is the pressure signals measured at rest and proximal to the stenosis (point A) 2 Curves set 1 10 is the pressure signals measured at rest and distal to the stenosis (point B) 3
- Curves set 1 1 1 is the pressure signals measured during vasodilatation and distal to the stenosis (point B)
- Fig 32 illustrates the mean values of each set of the pressure curves shown in Fig 30, where Curve 1 12 is the mean value of the pressure signals measured at rest proximal to the stenosis (point A) Curve 1 13 is the mean value of the pressure signals measured at rest distal to the stenosis (point B), and Curve 1 14 is the mean value of the pressure signals measured during vasodilatation distal to the stenosis (point B)
- Fig 31 illustrates the non dimensional flow curves calculated from the curves of Fig 30
- the set of curves 1 15 describe the non dimensional flow during rest
- the set of curves 1 16 describe the non dimensional flow during vasodilatation
- Fig 33 describes the calculated mean non dimensional flow, where Curve 1 17 is the mean non dimensional flow at rest, and Curve 1 18 is the mean non dimensional flow during vasodilatation
- FIG 12 illustrating a cross section of an artery 30 having an arterial wall 32 and a stenosis 34
- Two points A and B upstream and downstream of the stenosis define a section of the artery
- the hemodynamic parameters CFR, DSVR, and FFR along the section are of interest
- a guiding catheter 3 (or diagnostic catheter) is inserted into the blood vessel of interest
- An external fluid filled pressure transducer 31 is connected to the guiding catherter entrance (proximal end) measuring the pressure at point C (fluid filled pressure)
- a guiding wire 6 having a pressure sensor at its tip 4 is inserted through the guiding catheter and positioned so that the pressure sensor 4 is located at point A downstream of the stenosis
- Both pressure sensors 4 and 31 are connected to the system 23 described in Figure 1 , 1 a, 1 b , 2, and 2 a Simultaneous ECG data is collected using standard instrumentation available at all times in all cathete ⁇ zation procedures
- Step 1 Simultaneous pressure and ECG measurements are performed
- the pressure transducer 4 is at point B Data of pressure versus time P RSt) and P RC( and ECG are acquired, while the patient is at rest condition
- Step 2 Induce vasolidation
- Step 3 Simultaneous measurements of pressure and ECG are repeated, yielding data of pressure verses time P RS(I) and P RC(t) and ECG The measurements are performed while the patient is at vasolidation condition Step 4 Pullback the pressure tansducer 4 to point A Step 5 Simultaneous measurement of ECG and pressure is repeated, yielding data of pressure versus time P ⁇ , and P C(I and ECG
- Fig 34 illustrating a cross section of an artery 30 having an arterial wall 32 and a stenosis 34
- the parameters CFR, FFR, and DSVR of this section are of interest
- a guiding catheter 3 (or diagnostic catheter, or any other hollowed catheter) is inserted into the blood vessel of interest
- the guide wire 6, having a pressure sensor at its tip 4 is inserted trough the guiding catheter and positioned so that the pressure sensor 4 is located at point A, proximal to the stenosis
- the pressure sensor 4 is connected to the system 23 described in Figs 1 ,1 a and 2,2 a
- Step 1 Measurement of pressure is performed by the pressure sensor 4, yielding Pr A (t) The measurement is performed while the patient is at rest condition
- Step 2 The pressure sensor 4 is moved upstream to point B .distal to stenosis Step 3: Measurement of pressure is performed by the pressure sensor 4, yielding
- Step 4 Induce vasodilatation Step 5 Measurement of pressure is performed by the pressure sensor 4, yielding Pv B (t) The measurement is performed during vasodilatation Step 6(opt ⁇ onal) Pressure sensor 4 is moved backward to point A, proximal to the stenosis, yielding Pv A (t) This step is optional The alternative is to rely on the 5 assumption that the pressure at point A during vasodilatation is equal to the pressure at point A during rest
- Optimal Overlap method is used to synchronize the pressure pulses i o measured at points A and B. Synchronization is achieved by moving the pressure signal measured at point B, so that its maximum value fits the maximum value of the other pressure signal (measured at point A) Now, simultaneous pressure data, proximal and distal to the stenosis, are available, and the hemodynamic parameters are calculated.
- a method for the determination of the hemodynamic parameters in a 25 non-obstructed vessel using a standard balloon, inserted into the blood vessel of interest Inflating the balloon induces an artificial obstruction
- the inflated balloon should not significantly impede the flow
- a minimal pressure gradient of about 4 mmHg in rest is required Pressures across the induced stenosis are obtained, and calculation of the hemodynamic Parameters are performed using one of the methods mentioned herein above
- the CFR 0 is then calculated according to the equations described herein above
- Fig 35 illustrating a cross section of an artery 30 having an arterial wall 32
- the parameter CFRo, of this section is of interest
- a guiding catheter 3 (or diagnostic catheter, or any other hollowed catheter) is inserted into the blood vessel of interest
- An external fluid filled pressure transducer 31 is connected to the guiding catheter ostium (proximal end) measuring the pressure at point C (fluid filled pressure)
- a guide wire 6, having a pressure sensor 4 at its tip is inserted through the guiding catheter and positioned so that the pressure sensor 4 is located at point
- Pressure sensor 4 is connected to system 23 described in Figs 1 ,1 a and 2,2 a
- a balloon catheter is then inserted into the blood vessel of interest 30 (not shown)
- Step 1 Simultaneous measurement of pressure is performed by the pressure sensors 4 and 31 , yielding Pr A (t) and Pr c (t) The measurements are performed while the patient is at rest condition Step 2 Reference is made to Fig 36 The pressure sensor 4 is moved to point B
- the balloon catheter 120 is inserted into the blood vessel 30 and positioned so that the balloon is located between points A and B At this stage the balloon 121 is inflated
- Step 3 Simultaneous measurement of pressure is performed by the pressure sensors 4 and 31 , yielding Pr B (t) and Pr c (t)
- Step 5 Simultaneous measurement of pressure is performed by pressure sensors
- the hemodynamic conditions of a healthy artery may be characterized by CFRo and the vascular bed index VBIo, where the index 0 refers to healthy vessels
- VBIo vascular bed index
- the new parameter VBIo that is introduced in the present study, is equal to the ratio of mean shear to mean pressure
- a numerical model of the blood flow in a vessel with a blunt stenosis and autoregulated vascular bed is used The exact autoregulation mechanism is unknown Therefore, two different possible autoregulation conditions were tested (i) constant wall shear stress and (n) constant flow The model is based on the comparison of flow in healthy and stenotic vessels
- METHOD 8 FFR calculation using moving pressure transducer.
- Fig 45 illustrating a cross section of an artery 30 having an arterial walll 32 and a stenosis 34
- Two points A and D upstream and downstream of the stenosis define a section of the artery
- the hemodynamic parameter FFR, along this section, is of interest
- Standard FFR measuiements proximal pressure P is measured by fluid fllled manometer distal pressure P ( is measured by Pressure Wire
- the pressure measured by fluid filled manometer may be different from aortic pressure due to improper height of the fluid filled pressure transducer This height must be adjusted when Pressure Wire transducer is put at the end of the guiding catheter
- the present system may easily require calibration between the two pressure sensors
- the same transducer is used to measure the pressure at the proximal and distal points.
- the Pressure Wire is put proximal to the stenosis.
- the Fluid filled pressure P, a and proximal pressure P a measured by Pressure Wire are 5 measured at point A and, subsequently, saved in the computer memory. Measurements are as follows: 1 measurement is performed at point A for about 10 seconds having about 12 pulses. Then move the transducer to point D and measure again for 10 seconds having about 12 pulses.
- the Pressure Wire is moved distal to the stenosis to point D.
- the Fluid filled pressure P ld and distal i o pressure P d measured by Pressure Wire during hyperemia are measured and, subsequently, saved in the computer memory. Then FFR is calculated using mean values of Pd and Pa measured by Pressure Wire.
- the pressure measured by Fluid Filled catheter is used only for correction in the change of the hemodynamic conditions.
- the maximum hyperemia is determined by calculating FFR for every heart beat.
- the following graph presents the two main parameters that affect the algorithm range of operation, and combines them in order to schematically present the active range of the algorithm.
- the invention also provides for various VB diseases: intrinsic, vasomotor aspects.
- the system provided herein which includes the Automatic Similar Transformation method was connected to a Siemens Cathcor cathlab monitor for acquisition of the aortirial pressure wave, the Radi pressure wave and the ECG.
- the ECG signal output included a triggering signal which processed ECG.
- the system included pressure wires and pressure wire interface box and a fluoroscopy system. The velocity signal was directly sampled and used the analogous output of the Endosonics FlowMap system and flow wires.
- Table 2 D.H.-. RCA 80-90% stenosis.
- Table 3 W.G. - CIRC 70-90% stenosis.
- Table 4 T. LAD 90% stenosis.
- HPG- ⁇ P vaS0 mean pressure gradient across stenosis during vasolidation
- AST Automatic Similar Transformation
- the animal was anesthetized, the chest opened and the heart exposed The LCX was then dissected to allow introduction of the pe ⁇ vascular flowprobe and the balloon occluder The animal was cathete ⁇ zed via the carotid, and a pressure wire was introduced Proximal and distal measurements were collected for each level of stenosis Vasodilatation response was induced using IC Papave ⁇ ne 4mg In the first two animals the vasodilatation dose for max hyperemic response was studied using a total occlusion technique A series of occlusions was introduced by slowly inflating the balloon occluder, or by using a snare. In each level of occlusion the required measurements were obtained. At each level of stenosis, the percent stenosis was estimated from a rentgen picture.
- the animals used were very stable and in a good physiological condition throughout the procedure.
- the target vessel was the LCX, where a straight section with no branches was easier to find. 5-6 levels of stenosis were induced in each animal. The level of stenosis was estimated after each measurement by a Rentgen picture.
- Vasodilator effect Vasodilatation was achieved by intracoronary Papaverine injection. The response to Papaverine was immediate, reaching the max hyperemia after about 45 sec. The data is presented in Table 6 and Figures 37 and 38. All together, 22 stenoses were studied, all shown in Figure 37. Very good correlation is observed between Automatic Similar Transformation (AST) method calculated parameters (CFR-AST) and the flow based CFR using the alleged gold standard CardioMed flowmeter (A-CFR). As expected, low correlation is observed only in few cases of very light stenosis (25%), where the pressure gradient reaches the low limit of the method. In Figure 38,21 of 22 values are presented and regressed. Only one point is excluded, representing a stenosis ⁇ 25%.
- Table 6 AST-CFR/FFR calculated values compared to flow based CFR and FF pressure.
- the measured hyperemic velocity corresponds to the measured hyperemic pressure gradient for a 52% stenosis, as shown in Table 10:
- the baseline velocity measured by the FlowWire is too low for the measured pressure.
- the HAPV (55 cm/s) and BAPV (27 cm/s) values were used instead of 50 cm/s and 30 cm/s as measured by Flow wire and obtain a CFR equal to 2.0 instead of 1 .7.
- PCI percutaneous coronary intervention
- PC1 currently is guided by anatomic rather than flow assessment of lesion severity.
- Physiologic parameters such as Coronary Flow Reserve (CFR) and Fractional Flow reserve (FFR) more accurately describe the severity of flow reduction but are cumbersome to measure clinically.
- CFR Coronary Flow Reserve
- FFR Fractional Flow reserve
- the System which includes the AST as described above, was connected to an Astro-Med cathlab monitor for acquisition of the arterial pressure wave and the ECG.
- a modified Radi Pressure Wire Interface Box was used to allow high frequency data acquisition.
- the pressure signal was directly sampled by the AST System.
- a Fluoroscopy system of the animal lab was used and a Transconic ultrasonic flowmeter (Model T206) with pehvascular flowprobes (2,3, and 4 mm). The flow signal was directly sampled by the AST System.
- the pigs were anesthetized, the chest opened and the heart exposed.
- the LAD was then dissected in two separate sites to allow introduction of the pehvascular flowprobe and the balloon occluder.
- One the preparation stage is over reference measurements are obtained.
- a series of occlusions is introduced by slowly inflating the balloon occluder. In each level of occlusion the required measurements for CFR/FFR calculations are obtained.
- Vasolidation was achieved eitehr by intracoronary Adenosine or intracoronary Papaverine injections.
- the effect of Papaverine is long (>3 min) but not different then the short effect of the Adenosine. Maximal hyperemia is achieved by both. When no effect was observed it was due to the compensatory vasolidation of the distal bed. The results are presented in Table 14 and Figure 39.
- BPG Base Pressure Gradient across stenosis at rest.
- HPG Pressure gradient across stenosis at vasolidation.
- intraluminal pressured derived coronary flow indices correlate closely with indices derived from Doppler flow data. Derivation of these indices from pressure is simpler and more reliable as this method is independent of velocity profiles which may be individually variable.
- the vascular bed index is the same for mother and daughter arteries, if the ratio of the diameters of these arteries follows Murray's law (the Murray law discussed in the paper Kassab G S , Fung Y B The pattern of coronary arteriolar bifurcations and the uniform shear hypothesis ) The VBI using human data obtained was calculated
Landscapes
- Health & Medical Sciences (AREA)
- Life Sciences & Earth Sciences (AREA)
- Heart & Thoracic Surgery (AREA)
- Medical Informatics (AREA)
- Physics & Mathematics (AREA)
- Cardiology (AREA)
- Biophysics (AREA)
- Pathology (AREA)
- Engineering & Computer Science (AREA)
- Biomedical Technology (AREA)
- Veterinary Medicine (AREA)
- Public Health (AREA)
- Molecular Biology (AREA)
- Surgery (AREA)
- Animal Behavior & Ethology (AREA)
- General Health & Medical Sciences (AREA)
- Physiology (AREA)
- Hematology (AREA)
- Vascular Medicine (AREA)
- Measuring Pulse, Heart Rate, Blood Pressure Or Blood Flow (AREA)
Abstract
The present invention relates to intravascular pressure measurement based devices and methods determining clinical parameters related to stenosis severity for improved clinical diagnosis and treatment of cardiovascular disease in blood vessels or tubular conduits. More specifically, the invention provides methods for the determination of the clinically significant well known Coronary Flow Reserve (CFR) parameter-previously acquired by velocity measurement devices. In addition Coronary Flow Reserve in the same vessel without stenosis may be estimated and uses to select the necessary medical treatment. Additional pressure based clinical parameters, Diastole to Systole Velocity Ratio (DSVR) and Fractional Flow Reserve (FFR) in stenotic blood vessel during intervention (using only pressure measurements across stenosis) may also be calculated simultaneously, with the same set of interventional devices. Correlation of CFR with these parameters (e.g. FFR) may be further used to estimate the stenosis severity, downstream stenosis and the condition of the vascular bed or conditions related to aneurysms. It is known that there is a correlation between CFR and FFR for healthy vascular bed. Too low value of CFR for given FFR indicates either downstream flow restriction or insufficient infusion of vasodilator. Too high value of CFR for given FFR indicates vascular bed disease.
Description
A METHOD AND SYSTEM FOR PRESSURE BASED MEASUREMENTS OF CFR AND ADDITIONAL CLINICAL HEMODYNAMIC PARAMETERS
FIELD OF INVENTION
The present invention relates to the field of medical diagnostic and therapeutic devices in general and to a system for intravascular characterization of blood vessel lesions and vascular bed
BACKGROUND OF THE INVENTION Vascular diseases are often manifested by reduced blood flow due to atherosclerotic occlusion of vessels For example, occlusion of the coronary arteries supplying blood to the heart muscle is a major cause of heart disease Numerous methods are currently available for treating various lesion types Some of these methods are given herein below, sequenced from softer to heavier, relating to their ability to open calcified lesions, per cutaneous transluminal angioplasty (PTCA), Cutting balloon angioplasty, directional coronary atherectomy (DCA), rotational coronary atherectomy (RCA), Ultrasonic breaking catheter angioplasty, transluminal extraction catheter (TEC) atherectomy Rotablator atherectomy, and excimer laser angioplasty (ELCA ) Often, stents are placed within the lesion so as to prevent re-closure of the vessel (also known as recoil)
Lesion characteristics, together with vessel condition proximal and distal to the lesion and vascular bed condition are used to determine the medically and economically optimal treatment method or combination of methods of choice Geometry, pressure and flow are three variables often measured in the cardiovascular system These measurements are performed prior, during and after the treatment, providing diagnostic and therapeutic data The measurement prior to the treatment allows careful treatment selection Measurements during and after the treatment enable evaluation of the treatment efficacy Recent
progress in probe miniaturization opened a whole new range of pressure and flow measurements that have been previously impossible to perform
Lesion geometry is evaluated by angiography, qualitative coronary angiography (QCA), or by intravascular ultrasound (IVUS) These measurements allow calculation of the percent diameter stenosis (angiography or QCA) or percent area stenosis (IVUS) This information is used to estimate stenosis severity, but during the last years clinicians have realized that direct physical information about pressure and flow is necessary for complete evaluation of coronary artery disease Physiological measurements such as pressure gradient have been clinically used as an indicator for lesion severity However, previous attempts to relate the pressure gradient across the stenosis to its functional significance have been disappointing The decrease in the pressure gradient after PTCA has been used to assess the success of the treatment, with poor correlation. Other parameters have been defined and proven more effective as indicators for lesion severity The coronary flow velocity reserve (CFVR) is defined as the ratio of hyperemic to baseline flow velocity The fractional flow reserve (FFR) is defined as the ratio of distal (to stenosis) pressure (Pd) to aortic pressure (Pa) during hyperemia Hyperemic conditions are obtained by administration of vasodilators (e g papaveπne, adenosine) Clinical studies have demonstrated that in most cases, lesions with CFVR < 2 must be treated using one of the above mentioned methods, whereas for patients with CFVR > 2, angioplasty may be avoided Similarly, in most cases angioplasty may be avoided if FFR > 0 75 Coronary flow occurs essentially during diastole while systolic contribution to total coronary flow is smaller A notable difference between diastolic to systolic velocity ratio (DSVR) was observed between normal and stenotic arteries A cut-off value of 1 7 was proposed to distinguish between significant and non-significant lesions
The FFR and CFVR are independent but complementary indicators The first characterize the specific lesion whereas the second is a more global
parameter, characterizing the lesioned vessel (lesion and distal bed) Clinical studies (Di Mario et al , Catherization and Cardiac Diagnosis 38, 189-201 ,1996) show that for approximately 75% of the patients CFR and FFR lead to the same conclusion regarding the lesion significance At the same time, for 25% of the patients, the conclusions regarding lesion significance were different This means that simultaneous determination of coronary flow reserve and fractional flow reserve is highly important and gives the clinician the additional and more complete information regarding the lesion severity
Major technical progress has been made lately with respect to pressure and velocity monitoring guide wires For example, 0 014" Pressure Wire™ (Radi Medical System, Uppsala, Sweden) is now available for intracoronary pressure measurements However, for light stenosis, these measurements may be performed using diagnostic low profile catheters, Millar pressure transducer catheters (available by Millar Instruments, Ine , Houston, Texas, U S A ) or any other intravascular pressure equipment
A 0 014 Doppler Flow wire (Cardiometπcs Ine , Mountain View, CA) is now available for intracoronary velocity measurements Both wires may be advanced into distal parts of the coronary tree without significantly impeding the flow Simultaneous measurements of FFR and CFVR require the use of both wires Such a procedure is complicated, expensive and was used only for research purposes Therefore, clinicians use either velocity measurements to calculate coronary flow velocity reserve (CFVR) or pressure measurements to calculate fractional flow reserve (FFR) Furthermore, working with the Flow wire is sensitive to the location of the tip within the vessel cross section The wire tip will measure accurately if located along the longitudinal axis However, significant errors will appear once the wire is within the boundary layer Therefore, manipulating the Flow wire requires high expertise and a lot of experience Fortunately, these limitations are not relevant to the pressure wire measurements, yielding accurate data with simple handling
SUMMARY OF THE INVENTION
This invention provides a method for calculating the flow-based clinical characteristics, coronary flow reserve (CFR) and diasto c to systolic velocity ratio (DSVR), in addition to the FFR, using pressure measurements across a stenosis In addition coronary flow reserve in the same vessel without stenosis (CFR0) may be estimated as well as aneurysms FFR, CFR, CFR0 and DSVR are simultaneously calculated for a complete characterization of the vessel of interest . Further, the present invention relates generally to a sensor apparatus for determination of characteristics in a tubular conduit, such as a blood vessel or the urethra, having at least one pressure sensor adapted to measure pressure across an obstruction
This invention provides, a processor unit operatively connected to the at least one sensor, and a program for controlling the processor unit The processor unit is operative with the program to receive signals from the sensor, identify changes in the sensor signal, detect characteristics of the tubular conduit, the characteristics of the tubular conduit being derived from changes in the sensor signal, and recognize and assign a label to the characteristic of said tubular conduit This invention provides a system which includes the Automatic Similar Transmission method The characteristics that may be determined include a flow ratio in a blood vessel, a coronary flow reserve in a blood vessel diastole to systole velocity ratio in a blood vessel, coronary flow reserve together with fractional flow reserve in the same blood vessel without stenosis and analysis of their correlation for estimation of vascular bed conditions, coronary flow reserve together with fractional flow reserve in the same blood vessel without stenosis for estimation of vasodilatation effectiveness
Further, this invention provides the determination of a hemodynamic condition of the artery by determining the vascular bed index (VBI0) which is equal to the ratio of mean shear to mean pressure The invention provides a system and methods for determining the vascular bed index
Further, the present invention provides a methods of determining/detecting microvascular disease due to the abnormal ratio of FFR to CFR based on either or proximal and/or distal pressure The method may be in combination with a balloon procedure Also, the methods described provide for post PTCA evaluation (prior to stenting), determination or validation of dilatation success by subsequent CFR increase after PTCA, and indication of whether a stent is neded The methods and systems provided herein, indicate high probability of microvascular disease, due to the abnormal ratio of FFR to CFR Further, Post Stenting in combination with a deflated balloon allows the estimation of CFR of the vessel Thus, in one embodiment of the invention only a distal pressure measurement will allow the CFR calculation
Lastly, this invention provides determining CFR and FFR directly from intraarterial pressure measurements, thus the simultaneous CFR and FFR measurements permit one to obtain additional information about the vascular bed The present invention provides the hemodynamical parameters in estimating the severity of stenotic blood vessels in an attempt to increase the reliability of these parameters
BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be understood and appreciated more fully from the following detailed description taken in conjunction with the appended drawings in which like components are designated by like reference numerals Fig 1 is a schematic isometric view of a system for determining blood vessel hemodynamic parameters, constructed and operative in accordance with a preferred embodiment of the present invention
Fig 1 a are schematics isometric view of a system for determining blood vessel hemodynamic parameters, constructed and operative in accordance with another preferred embodiment of the present invention,
Fig 1 b are schematics isometric view of a system for determining blood vessel hemodynamic parameters, constructed and operative in accordance with another preferred embodiment of the present invention,
Fig 2 is a schematic functional block diagram illustrating the details of the system 1 of Fig 1 ,
Fig 2 a is a schematic functional block diagram illustrating the details of the system 1 a of Fig 1 a,
Fig 3 is a schematic isometric view of a part of system 1 or 1 a of Fig 1 or 1 a, constructed and operative in accordance with another preferred embodiment of the present invention,
Fig 4 is a schematic isometric view of an in-vitro system, constructed and operative in accordance with a preferred embodiment of the present invention,
Fig 5 is a schematic detailed illustration of the in-vitro tubing system 51 of Fig 4
Fig 6 is a detailed schematic illustration of the experimental section 44 of Fig 5 and the positioning of the pressure sensors within a the latex tube during the operation of the system of Figs 4 and 5
Fig 7 is a schematic cross section illustrating an artery with a stenosis and points A and B designating pressure measurement points
Fig 8 is a schematic cross section of a blood vessel, illustrating the positioning of the two pressure sensors used in Method 1 Fig 9 is a schematic cross section of a blood vessel, illustrating the positioning of the pressure sensors used in Method 2
Fig 10 presents an example of pressure data used by Method 3 to determined hemodynamic coefficients
Fig 1 1 presents the result of the calculation performed on the data shown
Fig 12 is a schematic cross section of a blood vessel, illustrating the positioning of the pressure sensors used in Method 3
Fig 13 presents the positioning of pressure sensors and stenosis inside the latex test tube of the in-vitro system of Figs 4-6 This configuration was used to validate Method 1 , the transfer function method
Fig 14 illustrates a calculated pressure pulse by Method 1 , with the actual pressure pulse measured at that point
Fig 15 illustrates an artery with a stenosis, a fluid filled pressure catheter and a pressure wire Points A and B designate measurements points Fig 16 presents pressure and ECG data, measured on human at rest condition, used by Method 4 Fig 17 presents the ECG signals, at rest, after time transformation The transformation is done using Method 2
Fig 18 presents the fluid filled catheter pressure signals at rest and after synchronization of the pulses Fig 19 presents the synchronized pressure signals representing the pressure proximal and distal to the stenosis
Fig 20 presents ECG and pressure signals measured at point A during rest and at point B during vasodilatation state
Fig 21 presents ECG signals, at rest (point A) and during vasodilatation (point B), after synchronization, applying the transformation of Method 2
Fig 22 presents the fluid filled catheter pressure signals, at rest (point A) and during vasodilatation (point B), after synchronization of the pulses
Fig 23 presents the guide wire pressure signals, at rest (point A) and during vasodilatation (point B), after synchronization of the pulses Fig 24 presents the distribution of a set of synchronized and transformed pressure signals measured at rest and during vasodilatation, used for determining mean values of hemodynamic coefficients
Fig 25 presents the calculated values of the non-dimensional flow using the data shown in Fig 24 Fig 26 presents the calculated values of CFR and FFR for each pulse
Fig 27 presents the mean values over number of heartbeats of pressure at point A and point B at rest and vasodilation conditions
Fig 28 presents the calculated values of the non-dimensional flow using the data described in Fig 27 Fig 29 presents human data of ECG signals and pressure measurements during rest and vasodilatation These data are used to calculate hemodynamic parameters using synchronization by ECG signals
Fig 30 presents synchronized pressure signals during rest and vasodilatation Fig 31 presents non-dimensional flow curves calculated from the synchronized curves of Fig 30
Fig 32 presents the mean values of the synchronized pressure signals shown in Fig 30
Fig 33 presents the calculated mean non-dimensional flow used to determine hemodynamic parameters
Fig 34 illustrates the positioning of the pressure sensors and measurements location when using the method of synchronization by max pressure signal
Fig 35 illustrates the pressure measurement points inside a non-lesioned blood vessel Fig 36 illustrates a balloon artificial obstruction inside a non-lesioned blood vessel and pressure measurement distal to the balloon
Fig 37 In-vivo canine data of CFR -F which uses the Automatic Similar Transformation method and CFR flow
Fig 38 In-vivo canine data of CFR -F which uses the Automatic Similar Transformation method and CFR flow
Fig 39 In-vivo pig data of CFR -F which uses the Automatic Similar Transformation method and CFR flow
Fig 40 Results of flow calculation using only pressure measurements across stenosis
Fig 41 Results of flow calculation using only pressure measurements across stenosis
Fig 42 Results of VBI calculation based on human data
Fig 43 Block diagram of Automatic Similar Transformation (AST) Method Fig 44 In-vivo human data of CFR which uses the AST Method
Fig 45 illustrating a cross section of an artery 30 having an arterial walll 32 and a stenosis 34 Two points A and D upstream and downstream of the stenosis define a section of the artery The hemodynamic parameter FFR, along this section, is of interest
DETAILED DESCRIPTION OF THE INVENTION
The pressure gradient in a blood vessel without stenosis is small (pressure difference between two points 5cm apart is less then 1 mm Hg) The accuracy of the devices for pressure measurement, which are used in medicine for intracoronary pressure measurements does not allow accurate determination of such small pressure differences Therefore, one cannot make an accurate calculation of flow using these existing pressure measurement devices in a healthy non-stenosed vessel The situation is different if an obstruction exists in the blood vessel (stenosis or some artificial obstruction) The pressure difference across such an obstruction may reach 40-50 mmHg at rest and 60-70 mmHg during hyperemia This significant pressure difference may be measured with high accuracy and may be used for calculations of coronary flow reserve (CFR), using the methods and system presented herein This calculated CFR might be slightly different then the coronary flow velocity reserve (CFVR) as measured by the Flow wire The difference may arise from changes in the velocity profiles Limiting to the available technologies, accurate results may be achieved if the pressure difference across the stenosis at rest is more then 4 mmHg However, using advanced methods of analysis, will allow to reduce this limitation to about 0 5 mmHg
As provided herein, the methods and systems described allow the calculation of both coronary flow indices, CFR and FFR directly from intrarterial pressure measurements The pressure derived flow indices correlated with and accurately predicted actual flow measurements By applying the methods percutaneous coronary interventions (PCI) decisions may be accurately made so as to achieve reduction in flow limiting ischemia The results presented herein based on both a Computational Fluid Dynamic (CFD) simulation and confirmance by in-vivo experiments demonstrated that the methods and systems provided herein, at all levels of stenosis severity, pressure measurements derived indices of CFR and FFR had superior correlation with actual flow indices
Further, the present invention provides methods and a system for calculation of CFR and FFR from on line intra-artenal pressure measurements Intracoronary pressure measurements were made in patients undergoing diagnostic angiography with findings of lesions of questionable clinical significance (intermediate lesions of 50-70% visual stenoses severity) Basal pressure measurements proximal, distal and during trans-lesional pull back were made with the methods and systems provided herein Patients were given intracoronary adenosine to achieve maximal vasodilatation and measurements were taken
In the work of Wong M , V ayaraghavan G , Bae J H Shah P M " In Vitro Study of Pressure-Velocity Relation Across Stenotic Orifices, published in the American Journal of cardiology, v 56, pp 465-469 pressure - flow relation across stenotic orifices was investigated in pulsatile in-vitro model They had shown that for short stenosis the pressure - flow relation is independent of the orifice size, for a wide pressure range The relation is quadratic and crosses zero This means, that in short stenosis, the pressure gradient across the stenosis (Δp is a quadratic function of flow (Q) Δp = K Q2 (1 )
Where K is a constant determined solely by the stenosis diameter If pressure measurements are obtained simultaneously upstream of the stenosis and
downstream of the stenosis during rest and during hyperemia, then flow at rest across the stenosis may be calculated using the equation
And the hyperemic flow may be found using the equation
K) (3)
Where Δpresl , Qrest and Δphyper , Qhyper are the pressure differences across
J e stenosis and flow during rest and hyperemia respectively. The coronary flow reserve (CFR) is defined as the ratio of the mean hyperemic flow to the mean flow at rest and may be calculated if the pressure difference across the stenosis is known during rest and hyperemia.
liR
Assuming the stenosis geometry is similar during rest and hyperemia, then K in equations (2) and (3) cancels out
Therefore, the coronary flow reserve (CFR) may be calculated if the pressure difference across the stenosis is known during rest and hyperemia.
Equations (2) and (3) are valid only for short stenosis. In the case of an arbitrary stenosis, the pressure difference across the stenosis may be expressed as (Young
π
D F Tsai F Y Flow characteristics in model of arterial stenosis - II Unsteady flow J Biomechanics, 1973 vol 6, pp 547-559)
Δp =K1Q+K2Q2 +K3dQ/dt
5 In the physiological range, the first and last components of this equation are small With accuracy of 1 mmHg, equations (2) and (3) may be used If Δp across the stenosis is more then 4 mmHg, the accuracy of CFR calculation will reach (10%)
CFR0 is the coronary flow reserve of a healthy vascular bed without stenosis i o Using the following notations
Q mean flow over a heartbeat in a stenotic vessel at rest,
Qv mean flow over a heartbeat in a stenotic vessel during hyperemia
(vasodilatation),
Q N mean flow over a heartbeat in the same non-stenotic vessel at rest, 15 QNV - mean flow over a heartbeat in the same non-stenotic vessel during hyperemia (vasodilatation),
Pa Aortic pressure
Pd Mean distal pressure at rest Then,
2 0
Ov
CFR = CFR a = FFR = -- :
Q Q,
25 and,
CFR . = Q ^ . CFR Q
Q Q Q FFR Q N
The vascular bed autoregulation tends to compensate hydraulic resistance of the stenosis, so at rest Q = QN, hence CFRo =CFR / FFR
If CFR and FFR are known, then the coronary flow reserve (CFRO) in the same vessel, in case of healthy vascular bed, may be derived A too high or too low value of CFR0 indicates a non healthy vascular bed Too low value of CFR for given FFR indicates either downstream flow restriction (additional stenosis) or insufficient infusion of vasodilator Too high value of CFR for given FFR indicates vascular bed disease The last equation may be used for determination of coronary flow reserve by positioning an artificial obstruction in a blood vessel, as presented herein below
In the preferred embodiment, calculating CFR and FFR may be accomplished by dividing into pulses the proximal and distal pressure Dividing the pulses are known to those skilled in the art For example, one use an ECG signal or only using a pressure signal The Automatic Similar Transformation (AST) Method the steps of which are described in Figure 43 In one embodiment, the systems provided herein include the AST method
In the AST method, every pulse p(t) 0<t1 <t2 is mapped to the time interval [01 ] using the following transformation P(τ)=P((τ-t1 )/(t-t2))) 0<τ<1 Then mean pressure pulse P mean (τ) is calculated, using averaging over all pulses for a give τ Six pressure signals result mean proximal fluid filled pressure Fp(τ), mean proximal pressure, measured by pressure transducer Pp(τ), mean fluid filled pressure Fd(τ) and mean pressure transducer pressure Pd(τ) both measured at rest when pressure transducer is distal to stenosis mean fluid filled pressure Fv(τ) and mean pressure transducer pressure Pv(τ) both measured during vasolidation
when pressure transducer is distal to stenosis Pressure signals Pd(τ) and Pv(τ) are corrected to the changes in aortic pressure
Pd(τ)=Pd(τ) *mean(Fp(τ) )/mean(Fd(τ) )),
Pv(τ)=Pv(τ) *mean(Fp(τ) )/mean(Fv(τ) )), Now pressure Pp(τ), Pd(τ), and Pv(τ) are used to calculate CFR, FFR, and DSVR In the pulse detection using only pressure signal the pulse detection is based on the pressure signal measured by moving pressure transducer The pulse detection method consists from following stages
1 FFT (fast Fourier transform) of the measured pressure signal in proximal point at rest (P.(t)), in distal point at rest (P2(t)) and in distal point during vasodilatation (P (t))
2 The frequency corresponding to the maximum value of the Fourier coefficients in the interval (0 5 - 10 Hz) is used as the pulse frequency c , (for P, series), ω2 (for P2 series), o>3 (for P3 series). 3 For every pressure series P, pressure the times of every pulse maximums tιm are found using following steps a First maximum must be found in the interval 0<t< c *f, were f is the sampling rate b The pressure maximum number k is looking for in the interval (tm k 1+0 5*c .*f, tm k 1 +1 5*o *f)
4 Finding time Tm (, when pressure reach minimum in the time interval (tm k ,, tm Points Tm k are points of the beginning of the pulse number k (hence end of the pulse k-1 ) The measured pressure signal is now divided into pulses For pulse selection, the following steps are taken
1 For every pulse calculate length' Ip of the fluid filled (Pf) and pressure (Pr) signal using equation Ip = mean(P2)-mean(P)*mean(P), where mean is calculated over one heartbeat P means Pf or Pr
2 Only pulses with lpf/lp>thesh are considered (here Ip, and Ip are the length of fluid filled and pressure pulses respectively, tresh is a
number (in software realization tresh=0 1 )) This allows throwing away pulses with drug admission Every pulse is mapped to time interval (0,1 ) with sampling rate 200Hz as in the previous version of the algorithm Mean pulses P1m and P2m at rest are calculated from pressure series
P-,(t) and P2(t) as in the previous algorithm (for example P1m(k)=mean(P1(k)), 1 <k<200 tιme point number for interpolated pulse Mean value is calculated over all pulses remaining after stage
2) Due to difference of the pulse shape before and after stenosis the position of the pulse minimum may be different relative to the systole beginning To compensate, the following cycle pressure steps are taken
a Double pulse P2m P2m double(1 400)=[ P2m (1 200), P2m (1 200)] b Calculate
c Find kmιn, the value of k when s(k) reach minimum Instead P2m use P__ =P2 ll d0Ub,e(km n k„n+200) The steps of step 5 applied to every n-th pulse P n(1 200) remaining after stage 2 Then CFRn for this pulse is calculated using equation
c rR = (∑^P (/) - /i (/) '∑-/7 / ) - /> ( )
The pulse nmaλ when CFRn reach maximum must be found Mean pulse during vasodilatation P3 - is calculated as mean for 5 pulses nmax-2 nmax+2 Then CFR and FFR are calculated
9 d Double pulse P2 - P2Tldouble(1400)=[ P2ll (1200) P2m (1200)] e Calculate
i(λ)= ∑(P , „ ( +ι)-Pt (/))
f Find kmn, the value of k when s(k) reach minimum Instead P2m
USe P2m~P2mdouble(kτιπ ^,- + 200)
10 The steps of step 5 applied to every n-th pulse P3n(1200) remaining after stage 2 Then CFRn for this pulse is calculated using equation
CFR = (∑^P (/)-/> (ι)/∑ > (ι)-Pt (X)
I I
11 The pulse nmax when CFRn reach maximum must be found Mean pulse during vasodilatation P3τι is calculated as mean for 5 pulses n^a-,-2 n-nax+2 Then CFR and FFR are calculated
In another embodiment CFR may be calculated based on the difference across the stenosis may be estimated from the volume flow rate 0(t) the minimal stenosis cross-sectional area I and the healthy vessel cross-sectional area A using the Young-Tsai (Young D F Tsai F Y A flow characteristics in model of arterial stenosis A B II Unsteady flow J Biomechanics 1973 vol 6 pp 547-559) equation upon one-heart beat (u=Q/A0)
Δ/J = A // +λ // (1)
k =4 u k /{τ D )
Λ „ = "-2 ' I ' (0 83 ' / + I M * D )/(/) I )
u mean velocity CQ=1 1 AO cross-sectional area of a vessel
DO cross-sectional diameter of a vessel p blood density μ blood viscosity LS stenosis length
If mean(u2)=b»mean(u)2, then (HPG-hyperemic pressure gradient, BPG -
baseline pressure gradient) BPG =K1 *b*(Q/A0)2 HPG =K1 *b*(Qv/A0)2, Q, Qv - flow at rest and during vasodilatation respectively, then HPG/BPG= (Qv /Q)2
CFR= Qv /Q, hence CFR=sqrt(HPG/BPG) In another embodiment flow was calculated using only pressure measurements across a stenosis The flow (ml/min) in rest and after vasodilatation is determined based on measured FFR The following relation between FFR and % stenosis was determined
st nosis ) 8861 + 0 0641 FFR - 0 67^ / ER
(3)
If the % stenosis is known, then the mean velocity u may be calculated by Young&Tsai equation (without linear term) The flow Q may be calculated if the diameter d of the vessel is known (Q=u*πd /4) FFR can be used to estimate % stenosis As shown in Figure 40 hyperemic flow and flow at rest for all 4 dogs are presented The hyperemic results are acceptable for all dogs (correlation coefficient R=0 94) The correlation coefficient at rest is relatively low (R=0 77) mainly due the fourth dog Correlation between measured and calculated flow for
first 3 dogs is better, as may be seen from fig 41 a and 41 -b (R=0 88 at rest and R=0 95 during vasodilatation)
Reference is now made to Figs 1 , 1 a, 1 b 2 and 2 a Figs 1 , 1 a and 1 b 5 present a schematic isometric view of a system for determining blood vessel (lesion regions and non-lesioned regions) clinical hemodynamic characteristics CFR , DSVR and FFR The system is constructed and operative in accordance with two embodiment of the present invention (1 and 1 a) Fig 2 and 2 a are schematic functional block diagrams illustrating the details of the system 1 of Fig 1 and i o system 1 a of Fig 1 a
The systems 1 , 1 a, and 1 b include a pressure sensor catheter or guide wire 4 inserted into the vessel directly or via a catheter lumen 3 for measuring the pressure inside a blood vessel The lumen catheter may be a guiding catheter (e g 8F Archer coronary guiding catheter from Medtronic Interventional Vascular,
15 Minneapolis, U S A ) or a diagnostic catheter (e g Siteseer diagnostic catheter, from Bard Cardiology, U S A ), a balloon catheter (e g Supreme fast exchange PTCA catheter, by Biotronik GMBH & Co, U S A ) or any other hollow catheter System 1 and systems 1 a and 1 b may include one (4) or more (i e Fig 3) pressure sensors on guide wire and also a fluid filled (FF) pressure transducer 31
20 (standard catheteπzation lab equipment), connected via the end of the guiding catheter 3 for measuring the pressure inside a blood vessel In an exemplary embodiment the pressure sensor 4 can be the 3F one pressure sensor model SPC-330A or dual pressure catheter SPC-721 commercially available from Millar Instruments Ine , TX, U S A , or any other pressure catheter suitable for diagnostic 25 or combined diagnostic / treatment purposes such as the 0 014 guidewire mounted pressure sensor product number 12000 from Radi Medical Systems, Upsala, Sweden, or Cardiometπcs WaveWire pressure guidewire from Cardiometrics Ine an Endsonics company of CA U S A
The systems 1 , 1 a and 1 b also include a signal conditioner 23 such as a
30 model TCB-500 control unit commercially available from Millar Instruments, or Radi
Pressure Wire Interface Type PWI 10, Radi Medical Systems, Upsala, or other suitable signal conditioner The signal conditioner 23 is suitably connected to the pressure sensor 4 for amplifying the signals of the pressure sensor The system 1 further includes an analog to digital (A/D) converter 28 (i e Nl E Series 5 Multifunction I/O model PCI-MIO-16XE-10 commercially available by National Instruments, Austin, TX) connected to the signal conditioner 23 and to the FF pressure transducer 31 for receiving the analog signals therefrom The signal conditioner 23 may be integrated in the data acquisition card of the computer 20, or may also be omitted altogether, depending on the specific type of pressure i o sensors used
The system 1 a of Fig 1 a also includes a standard cardiac cathetenzation system 22, such as Nihon Kohden Model RMC-1 100, commercially available from Nihon Kohden Corporation, Tokyo, Japan The signal conditioner 23 and the FF pressure transducer 31 are directly connected to the monitoring system 22 The
15 ECG is also available from the monitor using standard equipment and procedures The system 1 a further includes an analog to digital (A/D) converter 28 connected to the output of the monitoring system 22 through a shielded I/O connector box 27, such as Nl SCB-68 or BNC-2090 commercially available from National Instruments, Austin, TX
20 The systems 1 and 1 a also include a signal analyzer 25 connected to the
A/D converter 28 for receiving the digitized conditioned pressure signals from the A/D converter 28 The signal analyzer 25 includes a computer 20 and optionally a display 21 connected to the computer 20 for displaying text numbers and graphs representing the results of the calculations performed by the computer 20 and a
25 printer 26 suitably connected to the computer 20 for providing hard copy of the results for documentation and archiving The A/D converter 28 can be a separate unit or can be integrated in a data acquisition card installed in the computer 20 (not shown) The computer 20 processes the pressure data, sensed by the pressure sensors 4 and acquired by the A/D converter 28 or the data acquisition card (not
30 shown) and generates textual, numerical and/or graphic data that is displayed on
the display 21 The system 1 b includes a single hardware box 29 containing all signal conditioning, calculations, archiving options and digital display and output to a printer 26
Reference is now made to Figs 4, 5 and 6 for purposes of illustration Fig 5 5 is a schematic diagram representing an in-vitro experimental apparatus constructed and operative for determining flow characteristics in simulated non-lesioned and lesioned blood vessels, in accordance with an embodiment of the present invention Fig 2 is a schematic functional block diagram illustrating the functional details of a system including the apparatus of Fig 5 and apparatus for i o data acquisition, analysis and display
The fluidics system 51 of Fig 5 is a recirculating system for providing pulsatile flow The system 51 includes a pulsatile pump 42 (model 1421A pulsatile blood pump, commercially available from Harvard Apparatus, Ine , Ma, U S A ) The pump 42 allows control over rate, stroke volume and systole / diastole ratio The
15 pump 42 re-circulates distilled water from a water reservoir 15 to a water reservoir 14
The system 51 further includes a flexible tube 43 immersed in a water bath 44, to compensate for gravitational effects The flexible tube 43 is made from Latex and has a length of 120 cm The flexible tube 43 simulates an artery The flexible
2 o tube 43 is connected to the pulsatile pump 42 and to other system components by Teflon tubes All the tubes in system 51 have 4 mm internal diameter A bypass tube 45 allows flow control in the system and simulates flow partition between blood vessels A Windkessel compliance chamber 46 is located proximal to the flexible tube 43 to control the pressure signal characteristics A Windkessel
25 compliance chamber 47 and a flow control valve 48 are located distal to the flexible tube 43 to simulate the impedance of the vascular bed The system 51 of Fig 5 further includes an artificial stenosis made of a tube section 55, inserted within the flexible tube 43 The tube section 55 is made from a piece of Teflon tubing The internal diameter 52 (not shown) of the artificial stenosis 55 may be varied by using
artificial stenosis sections fabricated separately and having various internal diameter
Reference is now made to Fig 6, which is a schematic cross sectional view illustrating a part of the fluidics system 51 in detail Pressure is measured along 5 the flexible tube 43 using a pressure measurement system including MIKRO-TIP pressure catheters 57,58 and 59, SPC-320, SPC-721 or SPR-524 pressure catheter, connected to a model TCB-500 control unit, commercially available from Millar Instruments Ine , TX, U S A The catheters 57,58 and 59 are inserted into the flexible tube 43 via the connector 10, connected at the end of the flexible tube i o 43 The catheters 57,58 and 59 include pressure sensors 24A, 24B and 24C, respectively, for pressure measurements A fluid filled pressure transducer 31 is connected to the system 51 via the end of the guiding catheter 3, inserted into the flexible tube 43 via the connector 9 The fluid filled pressure transducer 31 is connected to the system 51 , when additional pressure readings are needed, or in
15 place of an intravascular pressure transducer, according to the defined experiment
The system 51 of Fig 5 also includes a flowmeter 1 1 connected distal to the flexible tube 43 and a flowmeter 12 connected to the bypass tube 45 The flowmeters 1 1 and 12 are suitably connected to the A/D converter 28 The flowmeters 1 1 and 12 are model 1 1 1 turbine flow meters, commercially available
20 from McMillan Company, TX, U S A
Reference is now made to Fig 4 The system 41 includes the system 51 The system 41 also includes a signal conditioner 23 of the type sold as model TCB-500 control unit commercially available from Millar Instruments The signal conditioner 23 is suitably connected to the pressure sensors 24A, 24B and/or 24C
25 for amplifying the pressure signals The system 41 further includes an analog to digital converter 28 (E series Instruments multifunction I/O board 28 model PC-MIO-16E-4, commercially available from National Ine , TX, U S A ) connected to the signal conditioner 23 for receiving the conditioned analog signals therefrom The system 41 also includes a signal analyzer 25 connected to the A/D converter
30 28 for receiving the digitized conditioned pressure signals from the A/D converter
28 The signal analyzer 25 includes a computer (Pentium 586) 20, a display 21 connected to the computer 20 for displaying text numbers and graphs representing the results of the calculations performed by the computer 20 A printer 26 is suitably connected to the computer 20 for providing hard copy of the results for 5 documentation and archiving The computer 20 processes the pressure data which is sensed by the pressure sensors 24A, 24B and 24C and acquired by the A/D converter 28 and generates textual, numerical and graphic data that is displayed on the display 21
The I/O board was controlled by a Labview graphical programming software, i o commercially available from National Instruments Ine , TX, U S A 10 sec interval of pressure and flow data were sampled at 5000Hz, displayed during the experiments on the monitor and stored on hard disk Analysis was performed offline using Matlab version 5 software, commercially available from The MathWorks, Ine , MA, U S A
15 The system uses various methods to determine the hemodynamic parameters defined herein above CFR, DSVR, and FFR All the methods are based on measurement or calculation of the pressure gradient (pressure drop) between two points along a blood vessel or tubular conduit These two points may be located proximal and distal to a stenosis an aneurysm or a section of the vessel
20 where the wall characteristics are of interest
The methods described herein below are more efficient and accurate than the existing tools and methods First the possibility to obtain multiple parameters in one procedure with one set of equipment allows the physician to gain a more comprehensive estimation of the vascular bed condition Second, the pressure
25 based CFR estimation presented herein is more accurate and robust than the velocity based CFR The reasons for this include the change in the velocity prof lie between rest and vasodilatation conditions, the errors introduced due to mal- positioning of the sensor within the vessel cross-section and also patient breathing and motion Lastly, the methods presented here are less sensitive to instability
30 (drift or jump) of the pressure transducers, and when instability is identified,
correcting procedure is short and presents no further risk to the patient (no need to re-cross the lesion)
Reference is now made to Fig 7 describing a section of blood vessel 30 having an arterial wall 32 The artery 30 may also include a stenosis 34, obstructing the blood flow Points A and B are located proximal and distal to the stenosis The pressure over time, PA(t) and PB(t), enable the calculation of the above mentioned parameters
Depending on the parameter of interest, measurements of the pressure gradient across the stenosis or aneurysm during various physiological conditions are needed
1 REST condition The patient is in normal condition, without any effect of dragues causing changes in blood pressure or flow rate
2 HYPEREMIA / VASODILATATION condition The patient is under the influence of dragues causing dilatation of the vascular bed, resulting in an increase blood flow rate
3 SYSTOLE
4 DIASTOLE
CFR CALCULATION In order to estimate the CFR value, pressure measurements are performed with the patient in REST and HYPEREMIA conditions CFR parameter is calculated using the following equation
} J Pv , - Λ , ) dt _o _____
CFR
where
PvA and PvB Pressure during hyperemia at points A and B respectively
Pr and Pr Pressure at rest at points A and B respectively t Time
T Time of one heart beat
CFR CALCULATION using maximal diastolic flow maximum
The method of CFR calculation uses the pressure difference across the stenosis over a full heartbeat The methods provided herein provide for the calculation of CFR as the ration of the flow diastolic maximum during vasolidation and at rest (Figure 40) As shown in Figure 1 1 , the ratio of flows during vasolidation and rest is almost constant during systole Hence, as provided herein, CFR may be calculated as a ratio of maximal flows at rest and during vasolidation The flow is proportional to the square root of the pressure difference across a stenosis, yielding the following equation
This method of CFR calculation is beneficial foi stenosis with small mean pressure gradient at rest The maximal diastolic flow may be 1 5 - 2 times higher then the mean flow Therefore, the maximal flow pressure gradient at rest is 2-4 times higher than the mean pressure gradient As a result, good estimation of the CRR may be achieved even for pressure gradient at rest of 1 -2 mmHg or less This reduces a limitation is calculating the CFR parameter in cases where the pressure gradient across the stenosis is very low Consequently, allowing the calculation of the CFR parameter in most cases Accordingly, the present invention
provides a method which incorporates calculating CFR using flow integral or using maximal diastolic flow as hereinabove described
DSVR CALCULATION In order to estimate DSVR, pressure data is required at REST condition only The pressure gradient between points A and B during diastole and during systole are calculated separately Therefore, simultaneous pressure data
_ _at points A and B are required during systole and diastole DSVR parameter is calculated by using the following equation
J( PrdA - PrdB ) dt diastole
DSVR =
syslolθ
PrdA pressure at point A at rest during diastole PrdB pressure at point B at rest during diastole
PrsA pressure at point A at rest during systole
PrsB pressure at point B at rest during systole
FFR CALCULATION In order to estimate FFR, pressure data during HYPEREMIA condition is required
FFR parameter is calculated using the following equation
PvB FFR =
PvA where
PvB Mean pressure at point B during hyperemia Pv Mean pressure at point A during hyperemia
METHOD 1 : SIMULTANEOUS TWO SITES PRESSURE MEASUREMENTS
Reference is now made to Fig 8, illustrating a cross section of an artery 30 having an arterial wall 32 and stenosis 34 Two points, A and B proximal and distal to the stenosis define a section of the artery The hemodynamic parameters CFR, DSVR, and FFR, along this section are of interest
A guiding catheter 3 (or diagnostic catheter, or any other hollowed catheter) is inserted into the blood vessel of interest Two guide wires 6 and 7, each having a pressure sensor at the tip 4A or 4B, are inserted through the guiding catheter and positioned so that one pressure sensor (4A) is located at point A, proximal to the stenosis, and the second pressure sensor (4B) is located at point B, distal to the stenosis Both pressure sensors are connected to signal conditioners 23A and 23B, of the kind described in Figs 1 , 1 a and 2, 2 a
DATA ACQUISITION The following steps are performed to obtain the required data
Step 1 Simultaneous measurement of pressure is performed by the two pressure sensors, yielding Pr t) and PrB(t) The measurement is performed while the patient
Step 2 Simultaneous measurement of pressures is performed again, by the two pressure sensors, yielding PvA(t) and PvB(t) The measurement is performed while the patient is under the effect of vasodilation dragues
DATA ANALYSIS
All 3 parameters (CFR, DSVR, and FFR) are calculated using the equations mentioned herein above
METHOD 2: SIMULTANEOUS TWO SITES PRESSURE MEASUREMENT USING A FLUID FILLED PRESSURE TRANSDUCER
Reference is now made to Fig 9, illustrating a cross section of an artery 30 with an arterial wall 32 and a stenosis 34 Two points A and B upstream and downstream of the stenosis define a section of the artery The hemodynamic parameters CFR, DSVR, and FFR, of this section are of interest
A guiding catheter 3 (or diagnostic catheter, or any other hollowed catheter) is inserted into the blood vessel of interest The tip of the catheter is positioned at point A, at the proximal section of the vessel A pressure fluid filled transducer 31 is connected to the external end of the catheter (point C) and measures the pressure at that point A single guide wire (6) having a pressure sensor at its tip (4B), is inserted trough the guiding catheter and positioned so that the pressure sensor 4B is located at point B The pressure sensor is connected to a signal conditioner 23 as described in Figs 1 ,1 a and 2,2 a
The pressure gradient between points A and C (PA-PC) are known to be small Therefore, it is assumed that PA ( Pc In cases of severe or moderate stenosis, the pressure gradient is PB-PC > 10 mmHg The pressure difference PA-PC is negligible (comparing to PB-PC ) Therefore, the assumption that PA-PC does not affect the coefficients (CFR, DSVR and FFR) calculated values In cases of light stenosis the use of this method is not recommended
In another embodiment the pressure measured by the Pressure Wire, the mean fluid filled pressure pulse ff_m is corrected in accordance with the floowing equation for every pulse the correct pressure P measured by the Pressure Wire multiplicatively is Pc(t)=P(t)*ff(t)/ff_m(t) Here Pc(t)corrected pressure, ff(t) pressure measured by fluid filled manometer
DATA ACQUISITION
The following steps are performed to obtain the required data
Step 1 Simultaneous measurement of pressure is performed by the two pressure sensors, yielding Prc(t) and PrB(t) The measurement is performed while the patient is at rest
Step 2: Simultaneous measurement of the pressure is repeated, yielding Pvc(t) and PvB(t) The measurement is performed while the patient is at vasodilatation condition
DATA ANALYSIS
PA is considered to be equal to Pc , (PA~PC) All 3 parameters (CFR, DSVR, and FFR) are calculated using the equations described herein above
CLINICAL EXAMPLE
Human test data are used to demonstrate the implementation of this method Pressure measurements were performed during rest and vasodilatation conditions The pressure was measured proximal to the stenosis (point A of Fig 9) using a fluid filled pressure sensor, and distal to the stenosis (point B of Fig 9) using Radi pressure wire
Reference is now made to Fig 10, illustrating the data acquired on paper (velocity of 25 mm/sec) The data was digitized using a computer software Graph 61 illustrates pressure data versus time during rest Curves Per and Pbr describe the pressure at points C and B, respectively Graph 62 illustrates pressure data versus time during vasodilatation Curves Pcv and Pbv describe the pressure at points C and B, respectively Due to the high pressure gradient across the stenosis (more than 10 mmHg at rest condition), the pressure measured by the fluid filled manometer (Pc) may be used instead of pressure data at point A
Reference is now made to Fig 1 1 which illustrates the calculated non-dimensional flow ratio versus time Then, the parameters CFR and FFR are calculated FFR = 0 46 and CFR = 1 48
IN-VITRO EXAMPLE
In vitro experiment was performed, using the in-vitro test system described in Figs 4, 5 and 6 The experimental section included an artificial stenosis (90% area reduction) Two pressure sensors (Millar SPC-524) were located, one 2 cm proximal to the stenosis and the second 2 cm distal to stenosis The system was running with a glycerin water solution to simulate blood viscosity
The system was run in two different modes to simulate rest and vasodilatation conditions These modes were obtained by changing three variables of the in-vitro system including the pump flow, the bypass opening and closure, and the height of the output reservoir Yielding various flow levels through the stenosis, with stable physiologic input pressure, simulating the aortic pressure Flowmeter 1 1 data and pressure data from both sensors were obtained in each system mode Applying the analysis described in Method 2 to this data yields the FFR and CFR values
The results are presented in Table 1 , where the cases refer to different levels of flow through the system
A high correlation is observed between CFR value derived from actual flow measurements and from pressure measurements
METHOD 3: NON-SIMULTANEOUS PRESSURE MEASUREMENTS WITH FLUID FILLED PRESSURE SYNCHRONIZATION
Reference is now made to Fig 12, illustrating a cross section of an artery 30 having an arterial wall 32 and a stenosis 34 Two points, A and B, proximal and distal to the stenosis define a section of the artery The parameters CFR, DSVR, and FFR of this section are of interest
A guiding catheter 3 (or diagnostic catheter, or any other hollowed catheter) is inserted into the blood vessel of interest 30 An external fluid filled pressure transducer 31 is connected to the guiding catheter ostium (proximal end), measuring the pressure at point C (referred as fluid field pressure)
One guide wire 6, having a pressure sensor at its tip 4 is inserted through the guiding catheter and positioned so that the pressure sensor 4 is located at point
A proximal to the stenosis The pressure sensor 4 is connected to system 23 described in Figs 1 , 1 a and 2, 2 a Then, the pressure sensor 4 is moved to point B for further measurements
DATA ACQUISITION
The following steps are performed to obtain the required data Step 1 The pressure sensor 4 is located proximal to the stenosis, at point A Step 2: Simultaneous measurement of pressure by the two pressure sensors, 4 and 31 are obtained, yielding PrA(t) and Pr-(t) The measurements are performed while the patient is at rest The pressure sensor 4 is moved to point B, distal to the stenosis Step 3: Simultaneous measurement of pressure is performed by the two pressure sensors, 4 and 31 Data of pressure versus time PrB(t) and Prc(t) is obtained
Step 4: Inducing vasodilatation
Step 5 Simultaneous measurement of pressure is performed by pressure sensors 4 and 31 , yielding PvB(t) and Pvc(t) The measurements are performed during vasodilatation condition Step 6: Pressure sensor 4 is moved backward to point A , proximal to stenosis
Step 7: Simultaneous measurement of pressure is performed by the pressure sensors 4 and 31 , yielding PvA(t) and Pvc(t) is obtained
DATA ANALYSIS To calculate hemodynamic parameters, simultaneous pressures at points
A and B are required Two independent methods where developed, synchronizing the pressure data at rest and vasodilatation conditions Once all pressures signals are available, the parameters CFR, DSVR, FFR are calculated using the equations mentioned herein above
Pressure Transfer Function
The measurements described previously are used to determine the transfer function of pressure between points C and A (Tea) using data acquired in step 1 Alternatively, transfer function between points C and B (Tcb) can be calculated, using data acquired at step 3 Once the transfer functions are known, pressure data at point A (or B) can be calculated from the known pressure at point C
Input
Data acquired at step 1 PrA1 (t) , Prc1 (t) Data acquired at step 3 PrB3(t) , Prc3(t)
Steps
Step 1 : Shift the pressure signal Prc1 (t) to yield a new pressure signal X1 (t) with mιn [X1 (t)] = 0, X1 (t) = Prc1 (t) - mm [Prc1 (t)]
Step 2: Shift the pressure signal PrA1 (t) to yield a new pressure signal Y1 (t) with mιn [Y1 (t)] = 0, Y1 (t) = PrA1 (t) - mιn[PrA1 (t)]
Step 3: Perform FAST FOURIER TRANSFORM (FFT) on X1 (t) and Y1 (t) Fx = FFT(X1 )
Fy = FFT(Y1 )
Step 4: Calculate the transfer function (H) in Fourier space H = Fy / Fx 5 Step 5 Calculate transfer function (Tea) in time space using INVERSE FAST FOURIER TRANSFORM (IFFT) Tca(t) = IFFT(H)
Step 6: Calculate pressure at point A, PrA3(t), from the known pressure at point C, Prc3(t), using convolution with the transfer function Tea PrA3 = CONV (Tea, Prc3) i o Now, the simultaneous pressure proximal and distal to the stenosis is known (PrA3 and PrB3) The same procedure is used to determine the simultaneous pressure, proximal and distal to the stenosis during vasodilatation (PvA5 and PvB5) The calculation of the parameters CFR, DSVR, and FFR is performed using the equation mentioned herein above
15
IN VITRO EXAMPLE
In vitro experiment was performed to validate the transfer function Method 1 , using the in-vitro test system described in Figs 4 5 and 6 The system was set
20 to 51 strokes/mm and 9 cc/stroke The system included a Latex test tube with a smooth stenosis model, 2cm long, with an internal diameter of 2 mm The stenosis was located 35 8 cm from the left bath edge Cordis 8F MPA-I was located within the connector 9 One pressure transducer was located along the latex tube Another pressure transducer was located within the guiding catheter to simulate 25 fluid filled pressure readings
Reference is now made to Fig 13, illustrating the positioning of the pressure sensors 24P and 24S, and the artificial stenosis 55, within the latex test tube, 43 The method 1 is applied to the pressure data at points S and P, to calculate the transfer function between these points, Tsp Then, the pressure at point D was
30 calculated using the pressure measured at point P, at a different time, and applying
the calculated transfer function This calculated pressure value was compared with the actual pressure at point D as was measured by the sensor 24D during the same heartbeat
The results are described in Fig 14 The graph designated 66, is the 5 calculated pressure at point P The graph designated 67, is the actual pressure measurement at point P, as measured by the sensor 24D during the same heartbeat Almost perfect match exists between the two curves (66 and 67)
Optimal Overlap Method: i o The idea of the Optimal Overlap method is based on the observation that fluid filled pressure wave pulse Pc(t) is mathematically similar to PA(t) but a delayed version of the latter Thus the best stretching coefficient β and the best delay Δt, for which the function β P2(T +Δt) is globally close to the foot of PA(t) is determined The reason for the appearance of the stretch coefficient (is a possible change in
15 pressure between measurements Mathematically, a minimum distance in L2 norm, or equivalently a least square criterion is required Thus, the least square optimal overlap methods can be formulated as follows
Let i be the index of N successive samples in the foot of the same heart beat (that 20 is from onset of systole to, say 80%, of the maximum of the pressure wave PA(t)) and t the corresponding sample times
METHOD 4 : NON-SIMULTANEOUS PRESSURE MEASUREMENTS WITH ECG SIGNALS SYNCHRONIZATION
25
Reference is now made to Fig 12, illustrating a cross section of an artery 30 having an arterial wall 32 and a stenosis 34 Two points A and B upstream and downstream of the stenosis define a section of the artery The hemodynamic parameters CFR, DSVR, and FFR, along this section are of interest
A guiding catheter 3 (or diagnostic catheter) is inserted into the blood vessel of interest An external fluid filled pressure transducer 31 is connected to the guiding catheter entrance (proximal end) measuring the pressure at point C (fluid filled pressure) A guide wire 6 having a pressure sensor at its tip 4 is inserted through the guiding catheter and positioned so that the pressure sensor 4 is located at point A downstream the stenosis Both pressure sensors 4 and 31 are connected to the system 23 described in Fig 1 ,1 a and 2,2 a
"Simultaneous ECG data is collected using standard available, at all times, in all cathetenzation procedures
DATA ACQUISITION
The following steps are performed to obtain the required data
Step 1 Simultaneous pressure and ECG measurements are performed Pressure are measured by two pressure sensors 4 and 31 Data of pressure versus time PrA(t) and Prc(t) and ECG are acquired, while the patient is at rest condition Step 2 Pressure sensor 4 is moved to point B, distal to stenosis Step 3 Simultaneous measurements of pressure and ECG are repeated, yielding data of pressure versus time PrB(t) and Prr(t) and ECG Step 4 Induce vasodilatation
Step 5 Simultaneous measurement of ECG and pressure is repeated yielding data of pressure versus time PvB(t) and Pvc(t), and ECG The measurements are performed while the patient is at vasodilatation condition Step 6 (optional) Pressure sensor 4 is pulled back to point A proximal to stenosis while simultaneous measurements of pressure and ECG are performed Data of pressure versus time PvA(t) and Pvc(t) and ECG chart are obtained
DATA ANALYSIS
To calculate hemodynamic parameters simultaneous pressure at points A and B during rest and vasodilatation are required The pressures at points A and B during
rest are measured, but non-simultaneously Time synchronization is performed using the idea that the ECG signals are stable while measuring pressure at points A or B Therefore, synchronizing the ECG signals, results in synchronization of the pressure signals at points A and B Synchronization is achieved by applying Method 2, with the ECG signals used instead of the fluid filled pressure signals For the vasodilatation condition, it is possible to measure pressure only at point B (downstream) The enlargement of the vessel wall during vasodilatation is negligible proximal to the stenosis, at point A Therefore, it can be assumed that PvA = PrA, and step 6 of this method may be skipped The simultaneous pressures at point A and B during vasodilatation is calculated Then, the parameters CFR, DSVR and FFR are derived using the equations mentioned herein above
CLINICAL TEST EXAMPLE 1
Data of pressure measurements of a 70 years old woman were used for estimation of CFR, DSVR and FFR The patient had two lesions in the mid and distal sections of the LAD
Reference is now made to Fig 15 Aortic pressure was measured with a fluid filled manometer (not shown) connected to the guiding catheter 93 Pressure in the LAD artery was measured using a Radi pressure wire 91 at point A upstream of the stenosis 92 Then, the pressure wire 91 was moved to measure the pressure at point B downstream of the stenosis Measurements at point A were made during rest, and at point B and C, during rest and during intracoronary adenosine injection (vasodilatation condition) Pressure signals from the fluid filled manometer, Radi guidewire pressure sensor 91 and ECG were simultaneously recorded and stored with sampling rate of 1 kHz
Data analysis included the calculation of CFR, DSVR and FFR using ECG synchronization Reference is now made to Fig 16, illustrating the pressure and ECG signals measured at rest (Radi pressure wire is located at point A and subsequently at point B) Curve 71 is the fluid filled pressure and Curve 72 is the pressure measured by sensor 91 , when the Radi pressure wire is at point A Curve
73 is the fluid filled pressure and Curve 74 is the Radi pressure measured at point B Curve 75 is the ECG signal measured when Radi pressure wire is at point A Curve 76 is the ECG signal measured when Radi pressure wire is at point B
The Optimal Method is used to move the section assigned 76-76a of the 5 ECG signal 76 (measured when pressure sensor 91 is at point B) to the section 75-75a of the ECG signal 75 (measured when Radi pressure wire is at point A) Linear time transformation is applied to the signal 76, in order to match the time length of the signals 75-75a and 76-76a The result of this transformation is shown in Fig 17, where the Curve 76t is the transformed ECG curve 76 i o The same time transformation (moving and stretching) is applied to the data measured by the fluid filled pressure transducer and Radi pressure wire The results of this transformation are shown in Figs 18 and 19 Fig 18 illustrates the measured fluid filled pressure, curve 71 , and the transformed fluid fllled pressure curve 73t Fig 19 describes the measured pressure at point A, curve 72, and the
15 transformed pressure of point B, curve 74t
The mean values, as measured by the fluid filled manometer when Radi pressure wire is at point A or B are different The pressure measured at point B by Radi pressure wire is corrected according to the observed difference of the mean fluid filled pressure signals The mean pressure correction turns the
20 calculation of the hemodynamic parameters using a moving pressure transducer more accurate, because it allows to exclude changes in the aortic pressure between measurements at points A and B Now the pressure measured at point A and the corrected pressure at point B (curves 72 and 74t on Fig 19) are used to calculate the non dimensional flow at rest The mean value of the non dimensional
25 flow is equal here to 1 8
Reference is now made to Fig 20, illustrating the pressure and ECG signals corresponding to vasodilatation condition The pressure upstream the stenosis (point A) during vasodilatation, is assumed to be equal in rest and vasodilatation conditions Curve 81 is the fluid filled pressure and Curve 82 is the Radi pressure,
30 measured when Radi pressure sensor 91 is at point A and during rest Curve 83
is the fluid fllled pressure and Curve 84 is the sensor 91 pressure, both measured when Radi pressure wire is at point B and during vasodilatation Curve 85 is the ECG signal measured when Radi pressure wire is at point A, at rest Curve 86 is the ECG signal measured when Radi pressure wire is at point B, during vasodilatation
The time transformation (moving and stretching) described herein above, is applied to the ECG measurements performed when Radi pressure wire is at point A at rest, and at point B during vasodilatation The moved and stretched ECG signal (curve 86t) and the ECG signal 85 are shown in Fig 21 The above analysis for data during vasodilatation is applied The results of the transformation are shown in Figs 22 and 23 Fig 22 illustrates the measured fluid filled pressure curve (81 ) and also the transformed fluid filled pressure curve (83t) Fig 23 describes the measured pressure curve at point A (82) and the transformed pressure curve of point B (84t) The mean value of the non dimensional flow during vasodilatation is 2 8 Now, the parameters of interest are calculated
FFR is calculated using the mean value of pressure measured at point A and the mean value of corrected pressure measured at point B, both during vasodilatation (shown in Fig 23), resulting in FFR=0 85 The suggested method of FFR calculation is more accurate then the standard method due to the fact that pressure data at point A is used instead of pressure data measured by fluid filled manometer
CFR is calculated as the ratio of the non dimensional flows during vasodilatation and rest CFR = 2 8 / 1 8 = 1 55
The procedure as described above, may be applied to a set of heartbeats Fig 24 illustrates synchronized and transformed pressure data at point A during rest (curves set 90), at point B during rest (curves set 91 ) and at point B during vasodilatation (curves set 92) Fig 25 illustrates the derived non-dimensional flow during rest (curves set 94) and during vasodilatation (curves set 93)
CFR and FFR values as calculated for each pulse are shown in Fig 26 The mean value of CFR is 1 63, and the mean value of FFR is 0 85 A different analysis
approach is to calculate the mean value of pressure (over multiple heartbeats), for every normalized (non-dimensional) time Fig 27 presents the pressure mean value at points A and B during rest (curves 95 and 96), and pressure at point B during vasodilatation (curve 97) Non-dimensional flow is calculated using these mean values, shown in Fig 28 Curve 98 is the calculated non dimensional flow during vasodilatation Curve 99 is the non dimensional flow during rest
CFR and FFR calculated this way are CFR= 1 61 and FFR= 0 87 These values are highly correlated to the values received above The data as shown in Fig 27 enables estimation of the third parameter mentioned above, the diastole to systole velocity ratio (DSVR) In this case DSVR=1 3
The parameters of interest were calculated for the same set of raw data using other methods proposed herein Using Method 2, Optimal Overlap Method CFR=1 92 , FFR=0 78 Using Method 5, synchronization by max pressure signal CFR=1 46 , FFR=0 81 , DSVR=1 15
CLINICAL TEST EXAMPLE 2
This example demonstrates the use of pressure data for CFR and FFR calculation using Method 4, ECG based signal synchronization The data includes blood flow measurements using the Flow wire by Endosonics, enabling the validation of the pressure based methods presented in this patent for derivation of CFR, FFR and DSVR It is shown that highly correlated values were derived for these parameters, using both methods
DATA ACQUISITION
The example is based on human pressure data measured in the LAD artery, using a standard fluid filled pressure transducer, Radi pressure wire by Radi Medical Systems AB, Uppsala, Sweden and doppler flow wire by Endosonics Data of ECG, pressures measured by Radi guide wire and fluid filled manometer were 5 recorded and printed simultaneously These data were scanned and digitized for computerized analysis Some fragments of the digitized pressure and ECG curves, are shown on Fig 29 The graph designated 106 describes pressure and ECG curves measured at rest while the Radi pressure sensor is located proximal to the stenosis (point A) i o The graph designated 107 describes pressure and ECG curves measured at rest while the Radi pressure sensor is located distal to the stenosis (point B) The graph designated 108 describes pressure and ECG curves measured during vasodilatation while the Radi pressure sensor is located distal to the stenosis (point B) Curve 101 in graphs 106, 107, 108 illustrates the fluid filled manometer
15 measurement Curve 102 in graphs 106, 107, 108 illustrates the pressure measurement measured by the Radi pressure sensor Curve 103 in graphs 106, 107, 108 illustrates the ECG measurement Note that only the main peak of the ECG signal was digitized These data were used for CFR calculation DATA ANALYSIS
20 Method 4 was applied to calculate CFR Results of calculations are shown in Figs 30, 31 , 32 33 Reference is now made to Fig 30 which illustrates three sets of pressure signals after ECG synchronization 1 Curves set 109 is the pressure signals measured at rest and proximal to the stenosis (point A) 2 Curves set 1 10 is the pressure signals measured at rest and distal to the stenosis (point B) 3
25 Curves set 1 1 1 is the pressure signals measured during vasodilatation and distal to the stenosis (point B)
Fig 32 illustrates the mean values of each set of the pressure curves shown in Fig 30, where Curve 1 12 is the mean value of the pressure signals measured at rest proximal to the stenosis (point A) Curve 1 13 is the mean value of the
pressure signals measured at rest distal to the stenosis (point B), and Curve 1 14 is the mean value of the pressure signals measured during vasodilatation distal to the stenosis (point B)
Fig 31 illustrates the non dimensional flow curves calculated from the curves of Fig 30 The set of curves 1 15 describe the non dimensional flow during rest The set of curves 1 16 describe the non dimensional flow during vasodilatation
Fig 33 describes the calculated mean non dimensional flow, where Curve 1 17 is the mean non dimensional flow at rest, and Curve 1 18 is the mean non dimensional flow during vasodilatation
From Fig 31 one may see, a major dispersion of the calculated flow during systole Flow calculated for various heartbeats during diastole is consistent The mean value of CFR (averaged over all heartbeats) is CFRm = 1 56 The mean value of FFR (averaged over all heartbeats) is FFRm = 0 79 In practice, CFR is usually determined as a ratio of the peak distal velocities In this case, the ratio of the flow at points M and N as marked in Fig 32 is CFRv = 1 86 Using the blood flow measurements during rest and during vasodilatation, CFR and FFR are calculated CFR = 1 8 and FFR = 0 75 The results using pressure measurements or flow rate measurements are highly correlated
METHOD 4A: PULLBACK PRESSURE MEASUREMENTS WITH ECG SIGNALS SYNCHRONIZATION
Reference is now made to Figure 12, illustrating a cross section of an artery 30 having an arterial wall 32 and a stenosis 34 Two points A and B upstream and downstream of the stenosis define a section of the artery The hemodynamic parameters CFR, DSVR, and FFR along the section are of interest A guiding catheter 3 (or diagnostic catheter) is inserted into the blood vessel of interest An external fluid filled pressure transducer 31 is connected to the guiding catherter
entrance (proximal end) measuring the pressure at point C (fluid filled pressure) A guiding wire 6 having a pressure sensor at its tip 4 is inserted through the guiding catheter and positioned so that the pressure sensor 4 is located at point A downstream of the stenosis Both pressure sensors 4 and 31 are connected to the system 23 described in Figure 1 , 1 a, 1 b , 2, and 2 a Simultaneous ECG data is collected using standard instrumentation available at all times in all catheteπzation procedures
DATA ACQUISITION The following steps are performed to obtain the required data
Step 1 Simultaneous pressure and ECG measurements are performed The pressure transducer 4 is at point B Data of pressure versus time PRSt) and PRC( and ECG are acquired, while the patient is at rest condition Step 2 Induce vasolidation
Step 3 Simultaneous measurements of pressure and ECG are repeated, yielding data of pressure verses time PRS(I) and PRC(t) and ECG The measurements are performed while the patient is at vasolidation condition Step 4 Pullback the pressure tansducer 4 to point A Step 5 Simultaneous measurement of ECG and pressure is repeated, yielding data of pressure versus time P^ , and P C(I and ECG
DATA ANALYSIS
To calculate hemodynamic parameters, simultaneous pressure at points A and B at rest and during vasolidation are required The pressures at points A and B during rest and vasolidation are measured but non-simultaneously Time synchronization is performed using the method that ECG signals are stable while measuring pressure points at A or B Therefore, synchronization of the ECG signals results in synchronization of the pressure signals at points A and B
Synchronization is achieved by applying the method relating to Method 2, with the Ecg signals used instead of the fluid filled pressure signals For the vasolidation condition, it is possible to measure pressure only at point B (downstream) since PVA = PRA Then, the parameters CFR, DSVR, and FFR are derived using the equations mentions hereinabove This method is more robust to changes in pressure accuracy due to drifting effects as the proximal and distal pressure measurements are taken in a short time
METHOD 5: SYNCHRONIZATION BY MAX. PRESSURE SIGNAL CLINICAL SYSTEM
Reference is now made to Fig 34, illustrating a cross section of an artery 30 having an arterial wall 32 and a stenosis 34 The points A and B .proximal and distal to the stenosis, define a section of the artery The parameters CFR, FFR, and DSVR of this section are of interest A guiding catheter 3 (or diagnostic catheter, or any other hollowed catheter) is inserted into the blood vessel of interest The guide wire 6, having a pressure sensor at its tip 4, is inserted trough the guiding catheter and positioned so that the pressure sensor 4 is located at point A, proximal to the stenosis The pressure sensor 4 is connected to the system 23 described in Figs 1 ,1 a and 2,2 a
DATA ACQUISITION
The following steps are performed to obtain the required data Step 1 Measurement of pressure is performed by the pressure sensor 4, yielding PrA(t) The measurement is performed while the patient is at rest condition
Step 2 The pressure sensor 4 is moved upstream to point B .distal to stenosis Step 3: Measurement of pressure is performed by the pressure sensor 4, yielding
PrB(t)
Step 4: Induce vasodilatation
Step 5 Measurement of pressure is performed by the pressure sensor 4, yielding PvB(t) The measurement is performed during vasodilatation Step 6(optιonal) Pressure sensor 4 is moved backward to point A, proximal to the stenosis, yielding PvA(t) This step is optional The alternative is to rely on the 5 assumption that the pressure at point A during vasodilatation is equal to the pressure at point A during rest
DATA ANALYSIS
Optimal Overlap method is used to synchronize the pressure pulses i o measured at points A and B. Synchronization is achieved by moving the pressure signal measured at point B, so that its maximum value fits the maximum value of the other pressure signal (measured at point A) Now, simultaneous pressure data, proximal and distal to the stenosis, are available, and the hemodynamic parameters are calculated.
15
Using the human test data described in Example 1 of Method 4 the following values are calculated
CFR = 1 46 FFR = 0 81 20 DSVR = 1 15
METHOD 6: INFLATED BALLOON CFR0 CALCULATIONS
A method is described for the determination of the hemodynamic parameters in a 25 non-obstructed vessel, using a standard balloon, inserted into the blood vessel of interest Inflating the balloon induces an artificial obstruction The inflated balloon should not significantly impede the flow However, a minimal pressure gradient of about 4 mmHg in rest is required Pressures across the induced stenosis are obtained, and calculation of the hemodynamic Parameters are performed using
one of the methods mentioned herein above The CFR0 is then calculated according to the equations described herein above
Reference is now made to Fig 35, illustrating a cross section of an artery 30 having an arterial wall 32 The points A and B, define a non-lesioned section of the artery The parameter CFRo, of this section is of interest A guiding catheter 3 (or diagnostic catheter, or any other hollowed catheter) is inserted into the blood vessel of interest An external fluid filled pressure transducer 31 is connected to the guiding catheter ostium (proximal end) measuring the pressure at point C (fluid filled pressure) A guide wire 6, having a pressure sensor 4 at its tip, is inserted through the guiding catheter and positioned so that the pressure sensor 4 is located at point A Pressure sensor 4 is connected to system 23 described in Figs 1 ,1 a and 2,2 a A balloon catheter is then inserted into the blood vessel of interest 30 (not shown)
DATA ACQUISITION
The following steps are performed to obtain the required data
Step 1 Simultaneous measurement of pressure is performed by the pressure sensors 4 and 31 , yielding PrA(t) and Prc(t) The measurements are performed while the patient is at rest condition Step 2 Reference is made to Fig 36 The pressure sensor 4 is moved to point B
The balloon catheter 120 is inserted into the blood vessel 30 and positioned so that the balloon is located between points A and B At this stage the balloon 121 is inflated
Step 3 Simultaneous measurement of pressure is performed by the pressure sensors 4 and 31 , yielding PrB(t) and Prc(t)
Step 4 Induce vasodilatation
Step 5 Simultaneous measurement of pressure is performed by pressure sensors
4 and 31 , yielding PvB(t) and Pvc(t) The measurements are performed during vasodilatation condition
DATA ANALYSIS
CFR and FFR are calculated for the balloon obstructed vessel using the procedure described in Method 2 However, all other methods (mentioned herein above) of clinical system for pressure measurements and calculation can be used together with balloon artificial obstruction
After CFR and FFR (for the balloon obstruction) are calculated, the mean values of the pressure gradient during rest (PArest-PBrest) and during vasodilatation (PArest-PBvaso) are calculated Then CFRo for the vessel without the obstruction, is calculated using the equation mentioned herein above
METHOD 7: CFD MODELING OF THE FLOW IN THE CORONARY ARTERY WITH STENOSIS. CFR AND FFR PARAMETERS.
Medical specialist estimate stenosis severity using either simple geometrical parameters, such as percent diameter stenosis, or hemodynamically based parameters such as the fractional flow reserve (FFR) or coronary flow reserve (CFR) As shown herein, the relationship between actual hemodynamic conditions and the above mentioned parameters of stenosis severity are established A numerical model of the blood flow in a vessel is used with a blunt stenosis and autoregulated vascular bed to simulate a stenosed blood vessel A key point to realistic simulations is to model properly the arterial autoregulation The present numerical model is based on the comparison 0 1 the flow in healthy and stenotic vessels The calculated values of CFR and FFR are in the physiological range
Results The hemodynamic conditions of a healthy artery may be characterized by CFRo and the vascular bed index VBIo, where the index 0 refers to healthy vessels The new parameter VBIo, that is introduced in the present study, is equal to the ratio of mean shear to mean pressure Instead of conducting hard to perform
in-vivo experiments, in the first stage of the study a numerical model of the blood flow in a vessel with a blunt stenosis and autoregulated vascular bed is used The exact autoregulation mechanism is unknown Therefore, two different possible autoregulation conditions were tested (i) constant wall shear stress and (n) constant flow The model is based on the comparison of flow in healthy and stenotic vessels
Conclusions Based on the results, the constant flow model of vascular bed autoregulation suggested in the present study allows using CFD to analyze different situations in clinical practice in an attempt to correlate between common hemodynamic parameters and the severity of stenosis
METHOD 8: FFR calculation using moving pressure transducer.
Reference is now made to Fig 45, illustrating a cross section of an artery 30 having an arterial walll 32 and a stenosis 34 Two points A and D upstream and downstream of the stenosis define a section of the artery The hemodynamic parameter FFR, along this section, is of interest
FFR is a ratio of distal (Pd) to proximal (P,) pressure (FFR=P( Pa)
Standard FFR measuiements proximal pressure P is measured by fluid fllled manometer distal pressure P( is measured by Pressure Wire The pressure measured by fluid filled manometer may be different from aortic pressure due to improper height of the fluid filled pressure transducer This height must be adjusted when Pressure Wire transducer is put at the end of the guiding catheter Thus, it will be appreciated that the present system may easily require calibration between the two pressure sensors
DATA ACQUISITION
The steps performed to obtain the required data will now be discussed. In the preferred method, the same transducer is used to measure the pressure at the proximal and distal points. The Pressure Wire is put proximal to the stenosis. The Fluid filled pressure P,a and proximal pressure Pa measured by Pressure Wire are 5 measured at point A and, subsequently, saved in the computer memory. Measurements are as follows: 1 measurement is performed at point A for about 10 seconds having about 12 pulses. Then move the transducer to point D and measure again for 10 seconds having about 12 pulses. The Pressure Wire is moved distal to the stenosis to point D. The Fluid filled pressure Pld and distal i o pressure Pd measured by Pressure Wire during hyperemia are measured and, subsequently, saved in the computer memory. Then FFR is calculated using mean values of Pd and Pa measured by Pressure Wire. The pressure measured by Fluid Filled catheter is used only for correction in the change of the hemodynamic conditions.
15 In the preferred method, the maximum hyperemia is determined by calculating FFR for every heart beat. An advantage of the present method is that automatic recognition of the intracoronary adenosine or papavehne injection and maximal hyperemia. Another advantage is that the transducer is less sensitive of the transducer to drifts. Thus, the present invention provides a means for reducing
20 sensitivity to drifts.
DATA ANALYSIS
Data analysis is performed using the AST to determine FFR as hereinabove described..
25
CLINICAL TEST EXAMPLE
Table 1 : CFR/FFR algorithm vs. traditional common practice tools.
+ small pressure difference ++ moderate pressure difference +++ high pressure difference
The following graph, presents the two main parameters that affect the algorithm range of operation, and combines them in order to schematically present the active range of the algorithm. The invention also provides for various VB diseases: intrinsic, vasomotor aspects.
EXAMPLE 1 : IN-VIVO CFR-FFR MEASUREMENTS IN HUMAN
SUBJECTS
Studies on human patients were conducted provided the results set forth in Figure 44 and Tables 2-5. The system provided herein which includes the Automatic Similar Transformation method was connected to a Siemens Cathcor cathlab monitor for acquisition of the aortirial pressure wave, the Radi pressure wave and the ECG. The ECG signal output included a triggering signal which processed
ECG. The system included pressure wires and pressure wire interface box and a fluoroscopy system. The velocity signal was directly sampled and used the analogous output of the Endosonics FlowMap system and flow wires.
Protocol: The patients studied with single lesion, double lesions, intermediate lesions. All the patients were symptomatic. CFR/FFR were measured using the pressure wires and flow wire simultaneously. Data analysis for comparison of pressure based and velocity based CFR estimation was done off-line.
Table 2: D.H.-. RCA 80-90% stenosis.
Table 3: W.G. - CIRC 70-90% stenosis.
File , CFR FFR BPG HPG Comment
12 44 16 1 .08 0.55 32.3 33.9 Vaso 1 i
12_52_ 27 1 .12 0.49 33.0 39.5 Vaso 2
13_00_ _52 4.0 0.89 0.39 7.8 After balloon - old proximal pressure
13_00_ _52 3.0 0.87 1 3 10 1 After balloon - new proximal pressure
Table 4: T. LAD 90% stenosis.
File CFR ! FFR BPG HPG I Comment
10 37 21 1 .04 0.68 37.3 40.3 ! Vaso 1
10 50 00 1 .2 ! 0.59 33.4 45.2 ! Vaso 2
10 50 00 3.2 ' 0.98 -0.7 1 .7 After balloon
Table 5: CLINIAL DATA REPORT: CFR AND FFR CALCULATIONS
CFR # automatic CFR calculation by the Endosonics system
CFR * CFR calculated based on flow raw data
BPG- ΔPres„ mean pressure gradient across stenosis at rest
HPG- ΔPvaS0, mean pressure gradient across stenosis during vasolidation
Results The results demonstrate that good correlation was found between the CFR-Automatic Similar Transformation (AST) method for CFR/FFR estimation to the velocity based CFR estimation In some case the CFR calculated based on velocity raw data actually resulted in a higher correlation, indicating problematic automatic CFR calculation of the Endosonics system The vasodilator/ effect was achieved by intracoronary Adenosine injection
EXAMPLE 2: IN-VIVO CFR-FFR MEASUREMENTS IN CANINES
Animal studies with 4 canines (20-25 Kg), were performed in a hospital in Japan The in-vivo studies set up included The Automatic Similar Transformation (AST) System connecting to a Nihon Kohden RM-6000 monitor for acquisition of the arterial pressure wave, a pressure signal, ECG and flow signal (fluoroscopy system which included a CardioMed CM2000 transit time and doppler flowmeter peπvascular handle flowprobes (3 mm)) The flow signal was presented on the monitor screen and sampled by the System which includes the AST method In these studies a FloWire was not used
Protocol The animal was anesthetized, the chest opened and the heart exposed The LCX was then dissected to allow introduction of the peπvascular flowprobe and the balloon occluder The animal was catheteπzed via the carotid, and a pressure wire was introduced Proximal and distal measurements were collected for each level of stenosis Vasodilatation response was induced using IC Papaveπne 4mg In the first two animals the vasodilatation dose for max hyperemic response was studied using a total occlusion technique A series of occlusions was introduced by slowly inflating the balloon occluder, or by using a
snare. In each level of occlusion the required measurements were obtained. At each level of stenosis, the percent stenosis was estimated from a rentgen picture.
Results: The animals used were very stable and in a good physiological condition throughout the procedure. The target vessel was the LCX, where a straight section with no branches was easier to find. 5-6 levels of stenosis were induced in each animal. The level of stenosis was estimated after each measurement by a Rentgen picture.
Vasodilator effect: Vasodilatation was achieved by intracoronary Papaverine injection. The response to Papaverine was immediate, reaching the max hyperemia after about 45 sec. The data is presented in Table 6 and Figures 37 and 38. All together, 22 stenoses were studied, all shown in Figure 37. Very good correlation is observed between Automatic Similar Transformation (AST) method calculated parameters (CFR-AST) and the flow based CFR using the alleged gold standard CardioMed flowmeter (A-CFR). As expected, low correlation is observed only in few cases of very light stenosis (25%), where the pressure gradient reaches the low limit of the method. In Figure 38,21 of 22 values are presented and regressed. Only one point is excluded, representing a stenosis < 25%.
Table 6: AST-CFR/FFR calculated values compared to flow based CFR and FF pressure.
Case # 0 //o Values AST Values
Stenosis FFR CFR FFR ; CFR
Dog 1 / 50% 0.84 4 , 0.77 ' 4.2 25Kg
i 75% 0.64 2.6 1 0.64 : 2.4
Discussion The significant difference (15-20 mm Hg) between the pressures measured by the fluid filled manometer and the Radi at the proximal point makes a direct estimation of the pressure gradient across the stenosis difficult For this reason, the pressure difference was computed taking into account the change in aortic pressure The mean pressure difference across the stenosis, denoted AP, is approximately 3 mm Hg 2 The pressure difference across the stenosis, Ap(t), may be estimated from the volume flow rate (in short flow) Q(t), the minimal stenosis cross-sectional area A, and the (healthy) vessel cross- sectional area A independent of geometry and can be approximated as 1 52 The coefficient (L,- length of the stenosis, D, and DO - diameters corresponding to the areas A, and Ao, respectively) Unfortunately, the functionof Q(t) is not known For estimation of the Q2 term it is assumed that Q(t) may be approximated as Q(l+sιn(27πt)), where Q is a constant Q2 = 1 5Q2 equal to mean flow The stenosis length Ls as well as Au are unknown However as the linear Poiseuille term ((the first term in Eq (2)) is small for typical stenosis, the representative values for the unknown parameters are taken Ls=2cm, Do=4mm Finally, it is assumed that blood viscositv u=0 O04 again due to the smallness of the Poiseuille term, the exact value of p is not important)
For definiteness two cases were examined, 1 ) 50% diameter stenosis, i e , A0/As =4 and 2) 60% stenoisis When there is 50% diameter stenosis, it was estimated that ΔP for various flow velocities u (Q = u*A0)
Table 7 50% diameter stenosis
Table 8 60% diameter stenosis, h/,4, =6 25
In the above Japan results the following pressure differences across stenosis were measured ΔPrest=3 4mm Hg, ΔPvaso= 19 7 mm Hg As shown in Table 7 (50% stenosis') that corresponding to a value of ΔPrest=3,4mm Hg there corresponds a value of velocity at rest Urest=l2cm/s and to ΔPvaso=19 7 mm there corresponds a value of velocity during vasodilatation Uvaso=40cm/s Therefore, CFR=40/12=3 3 Similarly, using Table 8 (60% stenosis) Urest=6cm/s, Uvaso=20cm/s and again CFR=20/6=3 3
During the experiment the velocity measured by the FlowWire in the above experiment was about 6 cm/s at rest and about 40 cm/s during vasodilatation The measured percent stenosis was 50% In this case, the velocity at rest is half the calculated velocity using pressure differences (Urest=l2cm/s) A possible explanation for this discrepancy is due to the misalignment of the FlowWire in the vessel
The above results of the FlowWire measurements confirm the proposition that baseline flows both in the stenosed and healthy vessel are the same Baseline flows before and after PTCA were 18 cm/s and hyperemic flow changed from 24 cm/s to 63 cm/s FFR=0 55-0 59 hence CFR/FFR = 2 26 - 2 42 CFR after PTCA equal to 63/24=2 62 The discrepancy is within 10%
Simultaneous CFR and FFR measurements permit one to obtain additional information about the vascular bed For example, in cases 4, 5 and 6 As in the previous report, one may use the Young and Tsai equation to calculate the flow in the stenosed blood vessel In case 4, the stenosis parameters are in this case 50% diameter stenosis, BAPV=l6cm/s, HAPV=44cm s, BPG=12 mm Hg, HPG=33 mm Hg , FFR=0 59- 0 63 Due to change in aortic pressure during vasodilatation the HPG is calculated using the mean aortic pressure measured at rest and FFR,
as well. It was assumed that stenosis has a length of L=2cm, artery diameter 3.0 mm, blood viscosity 0.0035. The results or the calculations are presented in Table. 9
Table 9. Calculations for LDA 50% diameter stenosis
From Table 9, that the measured velocities are small for a 50% stenosis. In this case, the CFR, which corresponds to the measured pressure gradients at rest and during vasodilatation is equal to 50/25=2.0 (which is the value computed using the methods described herein AST-CFR).
The measured hyperemic velocity corresponds to the measured hyperemic pressure gradient for a 52% stenosis, as shown in Table 10:
Table 10. Calculations for LDA 52% diameter stenosis
As demonstrated in Table 10 the baseline: velocity measured by the FlowWire is too low for the measured pressure. The baseline velocity corresponding to the base pressure gradient is 22 cm/s and CFR is again 44/22=2.0. The ratio CFR/FFR=2.0/0.63=3.2 3 is reasonable and doesn't seem to point to any problem with the vascular bed.
In case 5, LDA stenosis, its parameters are: 50% diameter stenosis, BAPV=IOcm/s, HAPV=34cm/s, BPG=12 mm Hg, HPG=34 mm Hg., FFR=0.66. Due
to change in aortic pressure during vasodilatation, the HPG is calculated using mean aortic pressure, measured at rest As in the previous case, stenosis length L=2cm, artery diameter 3 mm, blood viscosity 0 0035 Results or the calculations are presented in Table 1 1
Table 1 1 Calculations for LDA 50% diameter stenosis
The flow velocity at rest measured by FlowWire is too low for the measured pressure gradient, in this case also The corresponding CFR=37/18=2 is close to the value 1 8 supplied by the AST-CFR method The ratio CFR/FFR=2/0 66=3 is reasonable and doesn't seem to point to any problem with the vascular bed
Case 6, RCA stenosis Its parameters are 25% diameter stenosis, BAPV=3 Ocm/s, HAPV=50cmls, BPG=5 7 mm Hg, HPG= 15 9 mm Hg , FFR=0 83 Due to change in aortic pressure during vasodilatation the HPG is calculated using mean aortic pressure, measured at rest Stenosis is L-2cm, artery diameter 3 mm and blood viscosity at 0 0035 Results are presented in Table 12
Table 12 Calculations for RCA 25% diameter stenosis
The percent stenosis is too low for the measured velocities and the pressure gradients The CRR corresponding to the measured pressure gradient is 130/60=2 17 This value again is in good agreement with the AST-CFR method The following results were obtained were stenosis is 40%
Table 13. Calculations for LDA 40% diameter stenosis
In this case the CFR corresponding to the pressure gradient is 55/27=2.0, 10% less then the value calculated by the AST-CFR method. However, in this case where even a small error in the measured velocity or pressure gradient yields a 10-20% error in CFR. For example, in case 6, the HAPV (55 cm/s) and BAPV (27 cm/s) values were used instead of 50 cm/s and 30 cm/s as measured by Flow wire and obtain a CFR equal to 2.0 instead of 1 .7. The ratio CFR/FFR lies between 2.0/0.83=2.4 and 2.2/0.83=2.65. These values are near the lower bound of values CFR/FFR for normal vascular bed. Thus, there is a systematic error in the Flow Wire velocity measurements at velocities lower than 15-20 cm/s.
Conclusion: The above results demonstrate that the AST-CFR method is an accurate and more precise measurement of stenosis.
EXAMPLE 3: IN-VIVO CFR-FFR MEASUREMENTS IN SWINE
The goal of percutaneous coronary intervention (PCI) is to reduce flow-limiting arterial obstruction. PC1 currently is guided by anatomic rather than flow assessment of lesion severity. Physiologic parameters such as Coronary Flow Reserve (CFR) and Fractional Flow reserve (FFR) more accurately describe the severity of flow reduction but are cumbersome to measure clinically. As demonstrated herein, the methods of this invention, allow calculation of CFR and FFR directly from intraarterial pressure measurements.
Methods: In anesthetized pigs (30kg,) following throacotomy an occluder and ultrasonic flow probe (distal, Transonics) were placed around the LAD. A solid state
pressure guide wire (RADI Medical) and doppler flow wire (Endosonics) were placed in the LAD. Stenoses were established (30 - 70%)(n=IZ) and baseline and post-adenosine intracoronary pressure and flow measurements were made proximal, distal and during trans-lesional pullback. CFR and FFR were derived in real time from pressure via algorithm, and from actual measuredl flows. In 9 patients pressure and flow wires were placed proximal and distal to isolated coronary lesion (50 - 90 %), adenosine was administered and CFR and FFR were similarly derived.
The System which includes the AST as described above, was connected to an Astro-Med cathlab monitor for acquisition of the arterial pressure wave and the ECG. A modified Radi Pressure Wire Interface Box was used to allow high frequency data acquisition. The pressure signal was directly sampled by the AST System. A Fluoroscopy system of the animal lab was used and a Transconic ultrasonic flowmeter (Model T206) with pehvascular flowprobes (2,3, and 4 mm). The flow signal was directly sampled by the AST System.
Animal Preparation: The pigs were anesthetized, the chest opened and the heart exposed. The LAD was then dissected in two separate sites to allow introduction of the pehvascular flowprobe and the balloon occluder. One the preparation stage is over reference measurements are obtained. Then a series of occlusions is introduced by slowly inflating the balloon occluder. In each level of occlusion the required measurements for CFR/FFR calculations are obtained.
Vasolidation Effect: Vasolidation was achieved eitehr by intracoronary Adenosine or intracoronary Papaverine injections. The effect of Papaverine is long (>3 min) but not different then the short effect of the Adenosine. Maximal hyperemia is achieved by both. When no effect was observed it was due to the compensatory vasolidation of the distal bed.
The results are presented in Table 14 and Figure 39.
BPG: Base Pressure Gradient across stenosis at rest. HPG: Pressure gradient across stenosis at vasolidation.
In all pigs a close correlation was observed for pressure derived CFR (CFRP ) and FFR versus CFR (CFRF) and FFR derived from actual flow determination (CFRP=1 .03, CFRF=0.095, R=0.89). In the human subject the CFR and FFR correlated closely with flow velocity derived CFR and FFR (CFRP=1.06, CFRF=0.100, R=0.85).
Therefore, intraluminal pressured derived coronary flow indices correlate closely with indices derived from Doppler flow data. Derivation of these indices from pressure is simpler and more reliable as this method is independent of velocity profiles which may be individually variable.
EXAMPLE 4: IN-VIVO RESULTS OBTAINED BASED ON THE
AUTOMATIC SIMILAR TRANSFORMATION METHODS
The following results were obtained using the automatic similar transformation (AST) method described above.
Dog I -
EXAMPLE 5: VBI VERIFICATION
The vascular bed index is defined as VBI=( 4μQ)/(Pπd3)=( μu )/(Pd), where P -pressure, d- artery diameter, μ - dynamic viscosity The vascular bed index is the same for mother and daughter arteries, if the ratio of the diameters of these arteries follows Murray's law (the Murray law discussed in the paper Kassab G S , Fung Y B The pattern of coronary arteriolar bifurcations and the uniform shear hypothesis ) The VBI using human data obtained was calculated
The results are present in Fig 43a-d There is a strong correlation between VBI and mean flow velocity at rest with correlation coefficient R=0 926 (Fig 42a ) The mean value of the VBI=1 7» 105 The VBI is independent of the CFR, FFR and the ratio CFR/FFR (Fig 42b-d ) Hence, the VBI reflects another, then CFR and FFR, features of the vascular bed The low values of VBI indicate "slow flow" cases
EXAMPLE 6: VERIFICATION OF CFRO (the ratio CFR/FFR)
The calculated values of the CFR/FFR ratio are compared with in vivo test results. The results are presented and summarized in the following Table 15:
*CFR and FFR are calculated using the Automatic Similar Transformation method
Standard deviation of the CFR/FFR for every dog is also presented in the Table 15. The results for first 3 dogs confirm that CFR/FFR ratio is independent from % stenosis. In the Dog4 case the standard deviation is high. It is explained by the large disperse of ratio values.
Claims
1. A method for determination of flow ratio in blood vessel, said method comprising the steps of providing an apparatus adapted to measure pressure across a blood vessel obstruction.
2. The method of claim 1 for determination of coronary flow reserve in stenotic vessel including the steps of measuring pressure distal and proximal to said obstruction with said apparatus.
3. The method of claim 1 for determination of coronary flow reserve in a stenotic vessel including the steps of measuring aortic pressure and pressure distal to said obstruction, simultaneously by said apparatus having a fluid filled manometer and a pressure transducer, respectively.
4. The method of claim 1 for determination of coronary flow reserve in a stenotic vessel including the steps of: measuring aortic pressure with said apparatus having a fluid filled manometer; and measuring pressure across said obstruction with said apparatus having a moving pressure transducer.
5. The method of claim 1 for determination of coronary flow reserve in a stenotic vessel including the steps of: measuring aortic pressure with said apparatus having a fluid filled manometer; measuring pressure across said obstruction with said apparatus having a moving pressure transducer; and synchronizing said pressure measurements with said apparatus having an ECG.
6. The method of claim 1 for determination of coronary flow reserve in a stenotic vessel including the steps of: measuring pressure across said obstruction with said apparatus having a moving pressure transducer; and synchronizing said pressure measurements with said apparatus having an ECG.
7. The method of claim 1 for determination of coronary flow reserve in a stenotic vessel including the steps of: measuring aortic pressure with said apparatus having a fluid filled manometer; measuring pressure across said obstruction with said apparatus having a moving pressure transducer; and synchronizing said pressure measurements with said moving pressure transducer.
8. The method of claim 1 for determination of coronary flow reserve in a stenotic vessel including the steps of: vessel including the steps of: measuring aortic pressure with said apparatus having a fluid filled manometer; measuring pressure across said obstruction with said apparatus having a moving pressure transducer; and synchronizing said pressure measurements with said fluid filled manometer.
9. A method for determination of coronary flow reserve in a blood vessel including the steps of: providing an apparatus adapted to measure pressure across an artificial obstruction.
10. The method of claim 9 for determination of coronary flow reserve in a blood vessel including the steps of: providing said artificial obstruction; and measuring pressures across said artificial obstruction wherein an aortic pressure and a pressure distal to said obstruction, are simultaneously measured by said apparatus having a fluid filled manometer and a pressure transducer, respectively.
11. The method of claim 9 for determination of coronary flow reserve in a blood vessel including the steps of: providing said artificial obstruction; measuring an aortic pressure with said apparatus having a fluid filled manometer for the aortic pressure; and measuring pressure across the obstruction with said apparatus having a moving pressure transducer.
12. The method of claim 9 for determination of coronary flow reserve in a blood vessel including the steps of: providing said artificial obstruction; measuring an aortic pressure with said apparatus having a fluid filled manometer for the aortic pressure; measuring pressure across the obstruction with said apparatus having a moving pressure transduce; and synchronizing said pressure signals with said apparatus having an ECG.
13. The method of claim 9 for determination of coronary flow reserve in a blood vessel including the steps of: providing said artificial obstruction; measuring an aortic pressure with said apparatus having a fluid filled manometer for the aortic pressure; measuring pressure across the obstruction with said apparatus having a moving pressure transduce; and synchronizing said pressure signals with said moving pressure transducer.
14. The method of claim 9 for determination of coronary flow reserve in a blood vessel including the steps of: providing said artificial obstruction; measuring an aortic pressure with said apparatus having a fluid filled manometer for the aortic pressure; measuring pressure across the obstruction with said apparatus having a moving pressure transduce; and synchronizing said pressure signals with said fluid filled manometer.
15. A method for determination of diastole to systole velocity ratio in a stenotic vessel including the steps of: providing an apparatus adapted to measure pressure distal and proximal to a stenosis.
16. The method of claim 15 for determination of diastole to systole velocity ratio in a stenotic vessel including the steps of: measuring aortic pressure with said apparatus having a fluid filled manometer; and measuring pressure across said stenosis with said apparatus having a moving pressure transducer.
17. The method of claim 15 for determination of diastole to systole velocity ratio in a stenotic vessel including the steps of: measuring aortic pressure with said apparatus having a fluid filled manometer; measuring pressure across said stenosis with said apparatus having a moving pressure transducer; and synchronizing said pressure measurements with said apparatus having an ECG.
18. The method of claim 15 for determination of diastole to systole velocity ratio in a stenotic vessel including the steps of: measuring aortic pressure with said apparatus having a fluid filled manometer; measuring pressure across said stenosis with said apparatus having a moving pressure transducer; and synchronizing said pressure measurements with said moving pressure transducer.
19. The method of claim 15 for determination of diastole to systole velocity ratio in a stenotic vessel including the steps of: measuring aortic pressure with said apparatus having a fluid filled manometer; measuring pressure across said stenosis with said apparatus having a moving pressure transducer; and synchronizing said pressure measurements with said fluid filled manometer.
20. The method of claim 1 wherein said obstruction is a natural stenosis.
21. The method of claim 1 wherein said obstruction is an artificial balloon obstruction.
22. A sensor apparatus for determination of flow ratio in blood vessel comprising: at least one pressure sensor adapted to measure pressure across an obstruction.
23. The sensor apparatus of claim 22 for determination of coronary flow reserve in stenotic vessel wherein said at least one pressure sensor includes a plurality of pressure sensors adapted to measure pressure distal and proximal to said obstruction.
24. The sensor apparatus of claim 22 for determination of coronary flow reserve in a stenotic vessel wherein said at least one pressure sensor includes a fluid filled manometer and a pressure transducer adapted to simultaneously measure aortic pressure and pressure distal to said obstruction, respectively.
25. The sensor apparatus of claim 22 for determination of coronary flow reserve in a stenotic vessel wherein said at least one pressure sensor includes a fluid filled manometer adapted to measure aortic pressure and a pressure transducer adapted to measure pressure across to said obstruction.
26. The sensor apparatus of claim 22 for determination of coronary flow reserve in a stenotic vessel including: said at least one pressure sensor includes: a fluid filled manometer adapted to measure aortic pressure; and a pressure transducer adapted to measure pressure across to said obstruction; and an ECG cooperatively connected to said sensors for synchronization of the pressure signals.
27. The sensor apparatus of claim 22 for determination of coronary flow reserve in a stenotic vessel including: said at least one pressure sensor includes: a moving pressure transducer adapted to measure pressure across said obstruction; and an ECG cooperatively connected to said sensors for synchronization of the pressure signals.
28. The sensor apparatus of claim 22 for determination of coronary flow reserve in a stenotic vessel including: said at least one pressure sensor includes: a fluid filled manometer adapted to measure aortic pressure; and a pressure transducer adapted to measure pressure across to said obstruction; wherein said moving pressure transducer pressure measurements are used for synchronization of said pressure measurements.
29. The sensor apparatus of claim 22 for determination of coronary flow reserve in a stenotic vessel including: said at least one pressure sensor includes: a fluid filled manometer adapted to measure aortic pressure; and a pressure transducer adapted to measure pressure across to said obstruction; wherein said fluid filled manometer pressure measurements are used for synchronization of said pressure measurements.
30. A sensor apparatus for determination of coronary flow reserve in a blood vessel comprising: at least one pressure sensor adapted to measure pressure across an obstruction.
31. The sensor apparatus according to claim 29 for determination of coronary flow reserve in a tubular conduit or blood vessel wherein said at least one pressure sensor includes a fluid filled manometer and a pressure transducer adapted to simultaneously measure aortic pressure and pressure distal to said obstruction, respectively.
32. The sensor apparatus according to claim 30 for determination of coronary flow reserve in a blood vessel including: an artificial obstruction; said at least one pressure sensor includes: a fluid filled manometer adapted to measure aortic pressure; and a pressure transducer adapted to measure pressure across to said obstruction.
33. The sensor apparatus according to claim 30 for determination of coronary flow reserve in a blood vessel including: an artificial obstruction; said at least one pressure sensor includes: a fluid filled manometer adapted to measure aortic pressure; and a pressure transducer adapted to measure pressure across to said obstruction; and an ECG for synchronization of said pressure measurements.
34. The sensor apparatus according to claim 30 for determination of coronary flow reserve in a blood vessel including: an artificial obstruction; said at least one pressure sensor includes: a fluid filled manometer adapted to measure aortic pressure; and a pressure transducer adapted to measure pressure across to said obstruction; and wherein said moving pressure transducer pressure measurements are used for synchronization of said pressure measurements.
35. The sensor apparatus according to claim 30 for determination of coronary flow reserve in a blood vessel including: an artificial obstruction; said at least one pressure sensor includes: a fluid filled manometer adapted to measure aortic pressure; and a pressure transducer adapted to measure pressure across to said obstruction; and wherein said fluid filled manometer pressure measurements are used for synchronization of said pressure measurements.
36. A sensor apparatus for determination of diastole to systole velocity ratio in a stenotic vessel comprising: a plurality of pressure sensors adapted to measure pressure distal and proximal to a stenosis.
37. The sensor apparatus according to claim 30 for determination of diastole to systole velocity ratio in a stenotic vessel including: said plurality of sensors including: a fluid filled manometer adapted for aortic pressure measurements; and a moving pressure transducer adapted for pressure measurements across said stenosis.
38. The sensor apparatus according to claim 36 for determination of diastole to systole velocity ratio in a stenotic vessel including: said plurality of sensors including: a fluid filled manometer adapted for aortic pressure measurements; and a moving pressure transducer adapted for pressure measurements across said stenosis; and an ECG for synchronization of pressure signals.
39. The sensor apparatus according to claim 36 for determination of diastole to systole velocity ratio in a stenotic vessel including: said plurality of sensors including: a fluid filled manometer adapted for aortic pressure measurements; and a moving pressure transducer adapted for pressure measurements across said stenosis; and wherein said moving pressure transducer pressure measurements are used for synchronization of said pressure measurements.
40. The sensor apparatus according to claim 36 for determination of diastole to systole velocity ratio in a stenotic vessel including: said plurality of sensors including: a fluid filled manometer adapted for aortic pressure measurements; and a moving pressure transducer adapted for pressure measurements across said stenosis; and wherein said fluid filled manometer pressure measurements are used for synchronization of said pressure measurements.
41. A sensor system comprising: at least one sensor adapted to measure pressure in a tubular conduit across an obstruction.
42. The sensor system according to claim 40 including: means for determining a flow ratio in a blood vessel.
43. The sensor system according to claim 41 including: means for determining coronary flow reserve in a blood vessel.
44. The sensor system according to claim 41 including: means for determining diastole to systole velocity ratio in a stenotic vessel.
45. The sensor system according to claim 41 including: means for determining coronary flow reserve together with fractional flow reserve in the same blood vessel or tubular conduit without stenosis and analysis of their correlation.
46. The sensor system according to claim 41 including: means for determining coronary flow reserve together with fractional flow reserve in the same blood vessel without stenosis and analysis of their correlation for estimation of vascular bed conditions or an aneurysm.
47. The sensor system according to claim 41 including: means for determining coronary flow reserve together with fractional flow reserve in the same blood vessel without stenosis for estimation of vasodilatation effectiveness.
48. The sensor system according to claim 41 including said sensor being operative to generate a signal; a processor unit operatively connected to said at least one sensor; a program for controlling the processor unit; said processor unit operative with said program to: receive said sensor signal; identify changes in said sensor signal; detect characteristics of said tubular conduit, said characteristics of said tubular conduit being derived from changes in said sensor signal; and recognize and assign a label to said characteristic of said tubular conduit.
49. The sensor system according to claim 48 wherein said processor unit is operative with said program to determine a flow ratio in a blood vessel.
50. The sensor system according to claim 48 wherein said processor unit is operative with said program to determine coronary flow reserve in a blood vessel.
51. The sensor system according to claim 48 wherein said processor unit is operative with said program to determine diastole to systole velocity ratio in a stenotic vessel.
52. The sensor system according to claim 48 wherein said processor unit is operative with said program to determine coronary flow reserve together with fractional flow reserve in the same blood vessel without stenosis and analysis of their correlation.
53. The sensor system according to claim 48 wherein said processor unit is operative with said program to determine coronary flow reserve together with fractional flow reserve in the same blood vessel without stenosis and analysis of their correlation for estimation of vascular bed conditions.
54. The sensor system according to claim 48 wherein said processor unit is operative with said program to determine coronary flow reserve together with fractional flow reserve in the same blood vessel without stenosis for estimation of vasodilatation effectiveness.
55. The sensor system according to claim 48 wherein said processor unit is operative with said program to: determine a flow ratio in a blood vessel; determine coronary flow reserve in a blood vessel; determine diastole to systole velocity ratio in a stenotic vessel; determine coronary flow reserve together with fractional flow reserve in the same blood vessel without stenosis and analysis of their correlation for estimation of vascular bed conditions; determine coronary flow reserve together with fractional flow reserve in the same blood vessel without stenosis for estimation of vasodilatation effectiveness.
56. The sensor system of claim 48 wherein said at least one pressure sensor includes a plurality of pressure sensors adapted to measure pressure distal and proximal to said obstruction.
57. The sensor apparatus of claim 48 wherein said at least one pressure sensor includes a fluid filled manometer and a pressure transducer adapted to simultaneously measure aortic pressure and pressure distal to said obstruction, respectively.
58. The sensor apparatus of claim 48 wherein said at least one pressure sensor includes a fluid filled manometer adapted to measure aortic pressure and a pressure transducer adapted to measure pressure across to said obstruction.
59. The sensor apparatus of claim 48 including: said at least one pressure sensor includes: a fluid filled manometer adapted to measure aortic pressure; and a pressure transducer adapted to measure pressure across to said obstruction; and an ECG cooperatively connected to said sensors for synchronization of the pressure signals.
60. The sensor apparatus of claim 48 including: said at least one pressure sensor includes: a moving pressure transducer adapted to measure pressure across said obstruction; and an ECG cooperatively connected to said sensors for synchronization of the pressure signals.
61. The sensor apparatus of claim 48 including: said at least one pressure sensor includes: a fluid filled manometer adapted to measure aortic pressure; and a pressure transducer adapted to measure pressure across to said obstruction; wherein said moving pressure transducer pressure measurements are used for synchronization of said pressure measurements.
62. The sensor apparatus of claim 48 including: said at least one pressure sensor includes: a fluid filled manometer adapted to measure aortic pressure; and a pressure transducer adapted to measure pressure across to said obstruction; wherein said fluid filled manometer pressure measurements are used for synchronization of said pressure measurements.
63. The sensor system according to claim 48 wherein said sensor is moveable between proximal and distal ends of said obstruction and said tubular conduit is a blood vessel; said processor unit is operative with said program to: receive a first sensor signal when said sensor is at said proximal end and said blood vessel is at rest; receive a second sensor signal when said sensor is at said distal end and said blood vessel is at rest; receive a third sensor signal when said sensor is at said distal end and during vasodilation of said blood vessel.
64. The sensor system according to claim 63 wherein said processor unit is further operative with said program to: determine the amplitude and phase of said first, second and third sensor signals as a function of frequency.
65. The sensor system according to claim 64 wherein said processor with said program determines said amplitude and phase of said sensor signals by a fast Fourier transform.
66. The sensor system according to claim 64 wherein said processor with said program is operative to: determine a frequency for calculating said amplitude and phase of said first, second and third sensor signals.
67. The sensor system according to claim 64 wherein said processor with said program is operative to: determine a time in which a maximum value of said first, second and third sensor signals occurs.
68. The sensor system according to claim 67 wherein said processor with said program is operative to: determine a time in which a minimum value of said first, second and third sensor signals occurs.
69. The sensor system according to claim 68 wherein said processor with said program is operative to: exclude from said sensor signals, sensor signals that are representative of a pressure pulses influenced by drug admissions.
70. The sensor system according to claim 69 wherein said processor with said program is operative to: determine coronary flow reserve from said sensor signals.
71. The sensor system according to claim 69 wherein said processor with said program is operative to: determine fractional flow reserve from said sensor signals.
72. A method for determination of fractional flow ratio in a blood vessel, said method comprising the steps of providing an apparatus adapted to measure pressure across a blood vessel obstruction.
73. The method of claim 72 for determination of fractional flow reserve in stenotic vessel including the steps of measuring pressure distal and proximal to said obstruction with said apparatus.
74. The method of claim 72 for determination of fractional flow reserve in a stenotic vessel including the step of measuring pressure across said obstruction with said apparatus having a moving pressure transducer.
75. The method of claim 73 for determination of fractional flow reserve in a stenotic vessel including the steps of measuring pressure across said obstruction with said apparatus having a moving pressure transducer; and synchronizing said pressure measurements with said apparatus having an ECG.
76. The method of claim 73 for determination of fractional flow reserve in a stenotic vessel including the steps of: measuring pressure across said obstruction with said apparatus having a moving pressure transducer; and synchronizing said pressure measurements with said apparatus having an ECG.
77. The method according to any of steps 72-74 including repeating said measuring steps across said obstruction.
78. The method according to claim 77 including the step of calculating mean values representing a plurality of said measuring steps proximal and distal to said obstruction.
79. The method according to claim 78 including the step of determining a ratio of said proximal mean value and distal mean value.
Applications Claiming Priority (11)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US12349999P | 1999-03-09 | 1999-03-09 | |
US26478299A | 1999-03-09 | 1999-03-09 | |
US264782 | 1999-03-09 | ||
US123499P | 1999-03-09 | ||
US14079999P | 1999-06-25 | 1999-06-25 | |
US140799P | 1999-06-25 | ||
US09/344,505 US6471656B1 (en) | 1999-06-25 | 1999-06-25 | Method and system for pressure based measurements of CFR and additional clinical hemodynamic parameters |
US344505 | 1999-06-25 | ||
US15509599P | 1999-09-22 | 1999-09-22 | |
US155095P | 1999-09-22 | ||
PCT/IL2000/000148 WO2000053081A1 (en) | 1999-03-09 | 2000-03-09 | A method and system for pressure based measurements of cfr and additional clinical hemodynamic parameters |
Publications (1)
Publication Number | Publication Date |
---|---|
EP1251769A1 true EP1251769A1 (en) | 2002-10-30 |
Family
ID=27537662
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP00909600A Withdrawn EP1251769A1 (en) | 1999-03-09 | 2000-03-09 | A method and system for pressure based measurements of cfr and additional clinical hemodynamic parameters |
Country Status (4)
Country | Link |
---|---|
EP (1) | EP1251769A1 (en) |
JP (1) | JP2003525067A (en) |
AU (1) | AU3187900A (en) |
WO (1) | WO2000053081A1 (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US11039753B2 (en) | 2016-12-15 | 2021-06-22 | Baxter International Inc. | System and method for monitoring and determining patient parameters from sensed venous waveform |
US11039754B2 (en) | 2018-05-14 | 2021-06-22 | Baxter International Inc. | System and method for monitoring and determining patient parameters from sensed venous waveform |
Families Citing this family (42)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US6558334B2 (en) * | 2000-10-19 | 2003-05-06 | Florence Medical Ltd. | Apparatus for diagnosing lesion severity, and method therefor |
US6616597B2 (en) * | 2000-12-12 | 2003-09-09 | Datascope Investment Corp. | Intra-aortic balloon catheter having a dual sensor pressure sensing system |
US8200466B2 (en) | 2008-07-21 | 2012-06-12 | The Board Of Trustees Of The Leland Stanford Junior University | Method for tuning patient-specific cardiovascular simulations |
CA2734698C (en) | 2008-09-11 | 2012-05-01 | Acist Medical Systems, Inc. | Physiological sensor delivery device and method |
US9405886B2 (en) | 2009-03-17 | 2016-08-02 | The Board Of Trustees Of The Leland Stanford Junior University | Method for determining cardiovascular information |
US9301699B2 (en) | 2009-09-18 | 2016-04-05 | St. Jude Medical Coordination Center Bvba | Device for acquiring physiological variables measured in a body |
JP5688086B2 (en) * | 2009-09-18 | 2015-03-25 | セント ジュード メディカル システムズ アクチェボラーグ | Interception device |
EP2742858B1 (en) * | 2009-09-23 | 2024-06-05 | Light-Lab Imaging Inc. | Lumen morphology and vascular resistance measurements data collection systems, apparatus and methods |
US20180344174A9 (en) | 2009-09-23 | 2018-12-06 | Lightlab Imaging, Inc. | Lumen Morphology and Vascular Resistance Measurements Data Collection Systems, Apparatus and Methods |
US8315812B2 (en) | 2010-08-12 | 2012-11-20 | Heartflow, Inc. | Method and system for patient-specific modeling of blood flow |
GB201100137D0 (en) | 2011-01-06 | 2011-02-23 | Davies Helen C S | Apparatus and method of assessing a narrowing in a fluid tube |
GB201100136D0 (en) | 2011-01-06 | 2011-02-23 | Davies Helen C S | Apparatus and method of characterising a narrowing in a filled tube |
CN103796578B (en) | 2011-05-11 | 2016-08-24 | 阿西斯特医疗系统有限公司 | Ink vessel transfusing method for sensing and system |
US9339348B2 (en) * | 2011-08-20 | 2016-05-17 | Imperial Colege of Science, Technology and Medicine | Devices, systems, and methods for assessing a vessel |
US10888232B2 (en) | 2011-08-20 | 2021-01-12 | Philips Image Guided Therapy Corporation | Devices, systems, and methods for assessing a vessel |
JP6133864B2 (en) | 2011-08-20 | 2017-05-24 | ボルケーノ コーポレイション | Apparatus, system and method for visually depicting vessels and assessing treatment options |
SE537177C2 (en) * | 2011-10-28 | 2015-02-24 | St Jude Medical Systems Ab | Medical system for determining the Fractional Flow Reserve (FFR) value |
CA2861446A1 (en) * | 2012-01-19 | 2013-07-25 | Volcano Corporation | Interface devices, systems, and methods for use with intravascular pressure monitoring devices |
EP2832287B1 (en) | 2012-03-29 | 2017-04-26 | Terumo Kabushiki Kaisha | Image diagnosis device and probe |
EP3184048B1 (en) * | 2012-08-03 | 2021-06-16 | Philips Image Guided Therapy Corporation | Systems for assessing a vessel |
JP6381875B2 (en) * | 2012-08-16 | 2018-08-29 | キヤノンメディカルシステムズ株式会社 | Image processing apparatus, medical image diagnostic apparatus, and blood pressure monitor |
US20140086461A1 (en) | 2012-09-25 | 2014-03-27 | The Johns Hopkins University | Method and system for determining time-based index for blood circulation from angiographic imaging data |
EP2967370B1 (en) * | 2013-03-15 | 2021-09-29 | Philips Image Guided Therapy Corporation | Interface devices, systems, and methods for use with intravascular pressure monitoring devices |
US20150228115A1 (en) | 2014-02-10 | 2015-08-13 | Kabushiki Kaisha Toshiba | Medical-image processing apparatus and medical-image diagnostic apparatus |
US9974443B2 (en) | 2014-02-20 | 2018-05-22 | Koninklijke Philips N.V. | Devices, systems, and methods and associated display screens for assessment of vessels |
CA3186992A1 (en) * | 2014-04-04 | 2015-10-08 | St. Jude Medical Systems Ab | Intravascular pressure and flow data diagnostic systems, devices, and methods |
EP3133987B1 (en) | 2014-04-21 | 2019-09-11 | Koninklijke Philips N.V. | Sensing guide wire and method of manufacturing thereof |
US10244951B2 (en) | 2014-06-10 | 2019-04-02 | Acist Medical Systems, Inc. | Physiological sensor delivery device and method |
WO2016005944A1 (en) | 2014-07-11 | 2016-01-14 | Koninklijke Philips N.V. | Devices, systems, and methods for treatment of vessels |
US10849511B2 (en) | 2014-07-14 | 2020-12-01 | Philips Image Guided Therapy Corporation | Devices, systems, and methods for assessment of vessels |
WO2016008809A1 (en) | 2014-07-15 | 2016-01-21 | Koninklijke Philips N.V. | Devices, systems, and methods and associated display screens for assessment of vessels with multiple sensing components |
JP6596228B2 (en) * | 2015-04-28 | 2019-10-23 | フクダ電子株式会社 | Cardiac catheter testing device and method of operating cardiac catheter testing device |
US20180153415A1 (en) * | 2016-12-01 | 2018-06-07 | Edwards Lifesciences Corporation | Aortic stenosis classification |
EP3488774A1 (en) * | 2017-11-23 | 2019-05-29 | Koninklijke Philips N.V. | Measurement guidance for coronary flow estimation from bernoulli´s principle |
JP6974195B2 (en) * | 2018-01-26 | 2021-12-01 | 史靖 清家 | Calculation method of coronary blood flow reserve ratio, calculation device and program of coronary blood flow reserve volume ratio |
US10743774B2 (en) | 2018-04-20 | 2020-08-18 | Acist Medical Systems, Inc. | Assessment of a vessel |
EP3605554A1 (en) * | 2018-08-03 | 2020-02-05 | Koninklijke Philips N.V. | Blood flow measurement based on vessel-map slope |
USD926199S1 (en) | 2019-05-17 | 2021-07-27 | Opsens, Inc. | Display screen or portion thereof with graphical user interface |
KR102130254B1 (en) * | 2019-10-15 | 2020-07-03 | 주식회사 실리콘사피엔스 | Method and apparatus for simulating blood flow of a subject-specific blood vessel |
CN112617771B (en) * | 2020-12-28 | 2021-11-09 | 深圳北芯生命科技股份有限公司 | Method and system for determining diagnosis mode based on blood vessel congestion state |
CN114376546B (en) * | 2020-12-28 | 2024-03-12 | 深圳北芯生命科技股份有限公司 | System supporting double diagnosis modes |
JP2023074595A (en) * | 2021-11-18 | 2023-05-30 | 拓也 水上 | Compressed waveform standardization processing unit and program thereof |
Family Cites Families (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US5873835A (en) * | 1993-04-29 | 1999-02-23 | Scimed Life Systems, Inc. | Intravascular pressure and flow sensor |
JP3737554B2 (en) * | 1996-01-09 | 2006-01-18 | 株式会社東海理化電機製作所 | Catheter with sensor function |
US5775338A (en) * | 1997-01-10 | 1998-07-07 | Scimed Life Systems, Inc. | Heated perfusion balloon for reduction of restenosis |
-
2000
- 2000-03-09 JP JP2000603574A patent/JP2003525067A/en active Pending
- 2000-03-09 EP EP00909600A patent/EP1251769A1/en not_active Withdrawn
- 2000-03-09 AU AU31879/00A patent/AU3187900A/en not_active Abandoned
- 2000-03-09 WO PCT/IL2000/000148 patent/WO2000053081A1/en not_active Application Discontinuation
Non-Patent Citations (1)
Title |
---|
See references of WO0053081A1 * |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US11039753B2 (en) | 2016-12-15 | 2021-06-22 | Baxter International Inc. | System and method for monitoring and determining patient parameters from sensed venous waveform |
US11950890B2 (en) | 2016-12-15 | 2024-04-09 | Baxter International Inc. | System and method for monitoring and determining patient parameters from sensed venous waveform |
US11039754B2 (en) | 2018-05-14 | 2021-06-22 | Baxter International Inc. | System and method for monitoring and determining patient parameters from sensed venous waveform |
Also Published As
Publication number | Publication date |
---|---|
JP2003525067A (en) | 2003-08-26 |
AU3187900A (en) | 2000-09-28 |
WO2000053081A1 (en) | 2000-09-14 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US6471656B1 (en) | Method and system for pressure based measurements of CFR and additional clinical hemodynamic parameters | |
WO2000053081A1 (en) | A method and system for pressure based measurements of cfr and additional clinical hemodynamic parameters | |
US11950884B2 (en) | Devices, systems, and methods for assessing a vessel | |
US6193669B1 (en) | System and method for detecting, localizing, and characterizing occlusions, stent positioning, dissections and aneurysms in a vessel | |
JP7239644B2 (en) | Devices, systems and methods for grading vessels | |
US6354999B1 (en) | System and method for detecting, localizing, and characterizing occlusions and aneurysms in a vessel | |
US9931041B2 (en) | Method and apparatus for fractional flow reserve measurements | |
JP6214561B2 (en) | Interface device, system and method for use with an intravascular pressure monitoring device | |
EP3021741B1 (en) | System for assessing a vessel with automated drift correction | |
WO2001021057A2 (en) | A method and system for determination of ffr based on flow rate measurements | |
JP7117999B2 (en) | Endovascular processing system for assessment, planning and treatment of coronary interventions based on desired outcome | |
US20100125197A1 (en) | Method and apparatus for addressing vascular stenotic lesions | |
CN106535746B (en) | Devices, systems, and methods for vascular treatment | |
WO1999034724A2 (en) | Characterizing blood vessel using multi-point pressure measurements | |
US20140276137A1 (en) | Systems and methods for determining coronary flow reserve | |
WO2001013779A2 (en) | A method and system for stenosis identification, localization and characterization using pressure measurements | |
WO2000055579A2 (en) | A system and method for detection and characterization of stenosis, blood vessels flow and vessel walls properties using vessel geometrical measurements | |
EP1079727A1 (en) | Apparatus and method for identification and characterization of lesions and therapeutic success by flow disturbances analysis | |
WO2014150760A1 (en) | Perioperative feedback in endovascular aneurysm repair using physiological measurements | |
CN113558591B (en) | Intravascular pressure measurement system with visualization ring | |
JP2023535665A (en) | Systems and methods for tracking cardiovascular events with blood pressure | |
CN112494016A (en) | Method for tracking cardiac cycle events using blood pressure |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
PUAI | Public reference made under article 153(3) epc to a published international application that has entered the european phase |
Free format text: ORIGINAL CODE: 0009012 |
|
17P | Request for examination filed |
Effective date: 20010917 |
|
AK | Designated contracting states |
Kind code of ref document: A1 Designated state(s): AT BE CH CY DE DK ES FI FR GB GR IE IT LI LU MC NL PT SE |
|
STAA | Information on the status of an ep patent application or granted ep patent |
Free format text: STATUS: THE APPLICATION HAS BEEN WITHDRAWN |
|
18W | Application withdrawn |
Effective date: 20040303 |