FR2602663A1 - Probe and apparatus for measuring blood pressure, in particular in the ophthalmic artery - Google Patents

Abstract

The balloon probe for measuring blood pressure is characterised, according to the invention, in that the balloon 1 has a wall which is flexible but practically inelastic, and it is connected to a tube 2, the balloon/tube assembly being filled with liquid. The invention also relates to an apparatus for measuring blood pressure comprising the said balloon probe filled with liquid, connected to a manometric system M, and a probe 4 of a Doppler velocimeter D which can enter into contact with the wall of the balloon 1 and compress the latter. Medicine.

Description

The present invention relates to a new probe and a new non-invasive (non-bloody) measurement device for blood pressure, especially in the territory of the ophthalmic artery.

Traditionally, pressure measurements in the territory of the ophthalmic artery are carried out by ophthalmodynamometry, ophthalmodynamography or pneumoplethysmography.

Ophthalmodynamometry is a classic technique intended to measure the pressure in the ophthalmic artery by observing, using an ophthalmoscope, the appearance of pulsations in the central artery of the retina when an applied counterpressure is released. on the eye bulb. This technique has given rise to further improvements such as ophtaimodynamography (H. Hager, Klin. Mbl. Augenheilkunae 141, 801-840 (1962); and Wiener Med. Wschr. 39, 795-99, (1966) and other developments, in particular ocular pneumoplethysmography (Brockenbrough EC et al.,
Rev. Surg. 24, 299 (1967); W. Gee et al., Am. J. Surg.

130, 121-6 (1975).

Ophthalmodynamometry is a very cumbersome technique, requiring the presence of two manipulators, and moreover does not allow measurements to be made in people with opacity of the cornea, lens or vitreous body.

Ophthalmodynamography remains imprecise, however, because it uses pressure sensors which react appreciably to any change in volume, so that the measurement is affected by any involuntary movement of the eye muscles. Furthermore, the direction of the blood flow in the ophthalmic artery and its branches cannot be determined, the measurements are not reliable in pathology, in the event of collateralisation.

The technique of ocular pneumoplethysmography for the simultaneous determination of blood pressures in the ophthalmic artery and in the internal carotid artery requires the application of a vacuum of 300 to 500 mm Hg (40 to 66 kPa) on the sclera, which can lead to conjunctival bleeding. In addition, requiring the use of a local anesthetic, this technique is prohibited in subjects with conjunctivitis, glaucoma and detachment of the retina.

All these methods are quite complicated, difficult to implement, relatively expensive and not without risks for the patient.

We have now found an apparatus, comprising a balloon probe, and a method of measuring the ophthalmic pressure making it possible to determine the pressure of the internal carotid in this non-invasive manner, without inconvenience for the patient and requiring no pharmaceutical product. In addition, the technique according to the invention indicates the direction of the blood r-lux and its pressure in the branches of the ophthalmic artery
Balloon catheters have already been used in medicine, for example the Swann-Ganz catheter for cardiac catheterization. It is a probe whose end is surrounded by an inflatable balloon with air, the function of the balloon being to guide the probe through the cardiovascular system or to block its position. '' generally, balloons - especially for probes - are used in medicine for their capacity of distension. j
As will be seen below, the function and the use of the balloon according to the invention are quite different.

The invention therefore relates to a balloon probe for measuring blood pressure, in particular in the ophthalmic artery, characterized in that the balloon has a flexible but practically non-elastic wall, and it is connected to a conduit, the balloon-conduit assembly being filled with a liquid.

The balloon, or distal chamber, in particular has a substantially spherical shape, but may also have an ovoid, ellipsoid, hemispherical or even cylindrical shape, or a combination of these shapes, and its size is in relation to the caliber of the vessel on which the measurement pressure is performed (for example 1 to 4 cm in diameter, in particular approximately 1 to 2 cm for the territory of the ophthalmic artery).

The function of the conduit is to transmit the pressure exerted on the liquid contained in the balloon to a manometric measurement system. It can be flexible but practically non-distensible. The conduit as well as the balloon may in particular be made of a plastic material which is not very elastic, for example polyethylene, polypropylene, poly (vinyl chloride), etc., and may be in one piece or separate. The end of the conduit opposite the balloon may usefully include a connector and a valve, in particular a three-way valve.

The liquid filling the balloon and the conduit plays a double role: (1) transmission of the pressure caused by the compression of the balloon and (2) transmission of the ultrasound emitted by a Doppler velocimeter probe, using which one can also perform said compression.

The liquid can therefore be any substance insofar as it properly transmits pressure and ultrasound without damaging the materials which contain it, i.e. too viscous liquids, plastic solvents and aggressive substances are to avoid. You can just use water. The balloon should obviously not contain air bubbles.

The invention also relates to an apparatus for measuring blood pressure, especially in the ophthalmic artery, comprising a balloon probe filled with liquid, as described above, connected to a manometric system, and a Doppler velocimeter probe capable of come into contact with the wall of the balloon and perform compression of the latter.

The Doppler velocimeter probe is of the type commonly used in medicine and can be either continuous or pulsed emission; the continuous emission system, which is more manageable and less expensive, is suitable in the context of the invention.

The balloon probe with its conduit and the Doppler probe can be inserted and made integral with the same rigid tube, the Doppler probe being in contact with the balloon, and the balloon projecting at one end of the tube and being able to be applied. on the artery explored. This arrangement constitutes a compact probe which is easy to handle.

According to a variant, the invention provides a Doppler velocimeter probe on the end of which (sensor side) is fixed a balloon, in particular hemispherical, the duct of the latter being integrated in the Doppler probe.

 The invention will now be described in more detail with reference to the accompanying drawings showing exemplary embodiments.

In these drawings - Figure 1 shows a side view of a balloon probe according to the invention - Figure 2 shows a partial side view of a blood pressure measuring device comprising the balloon probe of Figure 1; and - Figure 3 shows a side view, a variant of the measuring device according to Figure 2.

 The probe shown in FIG. 1 comprises a balloon 1 having a flexible but practically non-elastic wall, connected to a conduit 2, the assembly being filled with a liquid such as water. The balloon 1 (distal chamber) has a substantially spherical shape (for example about 1.5 cm in diameter). The balloon and the flexible conduit (but with a thicker wall, of about 1 mm for example) are in one piece and can be made of a material such as polyethylene.

The end of the conduit 2 opposite the balloon has a connector 3, adaptable in particular to a three-way conduit, in order to allow it to be filled and emptied.

In FIG. 2 is shown an apparatus for measuring arterial pressure, in particular in the ophthalmic artery, comprising a balloon probe as represented in FIG. 1 (balloon 1 and conduit 2), as well as a velocimeter probe 4 Doppler in contact with the wall of the balloon 1.

The two probes 1 and 4 are inserted and made integral with the same rigid tube 5, for example metallic, the balloon 1 protruding at the lower end of the tube 5. The balloon 1 filled with a liquid, is connected by the conduit 2 and possibly via a three-way tap (not shown) to a manometer M with small breathing volume and, if necessary, to a liquid reservoir (not shown). The probe 4 is connected to a Doppler D velocimeter (not shown), in particular for medical use, for example. an Angiodop 481 device from the firm DMS-France. Such devices are commonly used for recording velocimetric curves in the diagnosis of arteries.

 The blood pressure measuring device shown in FIG. 3 comprises a Doppler velocimeter probe 4 on the lower end of which (on the side of the sensors 6) is fixed a balloon 1 in particular of hemispherical shape, connected to a conduit 2 Integrated in the Doppler 4 probe.

The balloon 1 and the probe 4 are respectively connected to the manometer M and to the velocimeter D.

The measurement method using the device according to the invention consists in applying an overpressure (eg 150 to 170 mm Hg or 20 to 22.6 kPa) on the artery, by pressing the balloon 1 on this last using the Doppler 4 probe, which temporarily blocks (a few seconds) the flow of the artery. By gradually releasing the pressure, it is then possible to precisely detect, using the Doppler probe, the moment when blood flow resumes in the artery. At this precise moment, the pressure applied (measured with the manometer M) becomes slightly lower than the systolic pressure of the artery from which an accurate measurement is thus obtained.

Indeed, the balloon probe, being filled with liquid, lets through the ultrasound emitted by the Doppler probe, which allows to locate the position of the artery and to record its signal.

In the case of the branches of the ophthalmic artery, the measurement corresponds in a normal subject to the pressure in the internal intracerebral carotid, as well as to that of the polygon of
Willis, and therefore to cerebral blood pressure.

The supra-orbital and frontal branches of the ophthalmic artery form anastomoses with the arterial branches of the face of the external carotid. The direction of flow is normally from the ophthalmic artery to these facial branches of the external carotid. If there is a stenosis or occlusion on the ophthalmic artery, or upstream of it, especially on the internal carotid artery, the blood flow is reversed in the branches of the ophthalmic artery. According to the invention, it is therefore possible to detect both the direction of the flow and the corresponding arterial pressure.

 With the apparatus according to the invention, the measurements of the arterial pressure can be carried out at different levels, for example - in peripheral territories of the limbs (radial, ulnar, pedal arteries, pulp plexus).

- in the territory of the external carotid artery (temporal artery and facial artery for example).

However, the advantage of this method lies in the ophthalmic territory.

This invention has many advantages over the techniques used to date, including great ease of use.

Claims (6)

1. Balloon probe for measuring arterial pressure, characterized in that the balloon (1) has a flexible but practically non-elastic wall, and it is connected to a duct (2), the balloon-duct assembly being filled with liquid. 2. Probe according to claim 1, characterized in that the balloon has a substantially spherical shape. 3. Blood pressure measuring device, characterized in that it comprises a balloon probe (1,2) according to claim 1 or claim 2, connected to a manometric system, and a probe (4) of Doppler velocimeter can come into contact with the wall of the balloon (1) and effect its compression.  4. Apparatus according to claim 3, characterized in that the balloon probe with its conduit (1,2) and the probe Doppler (4) are inserted and made integral with the same rigid tube (5 # the Doppler probe being in contact with the balloon (1), and the balloon (1) projecting at one end of the tube (5). 5. Apparatus according to claim 3, characterized in that the balloon (1) is fixed on the end of the probe (4) of the Doppler velocimeter, the conduit (2) being integrated in the probe (4). 6. Apparatus according to claim 5, characterized in that the balloon (1) is substantially hemispherical.