CN1531902A - Method for changing multiple synchronous electrocardiogram lead in corrected orthogonal electrocardiogram mode - Google Patents
Method for changing multiple synchronous electrocardiogram lead in corrected orthogonal electrocardiogram mode Download PDFInfo
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Abstract
The present invention features that the lead method of synchronous 18-lead electrocardiogram converted in corrected orthogonal electrocardiogram mode includes back left deriving V7, V8 and V9 as the three lead axes to reflect the back wall of the left ventricle with V6 lead as base point, right deriving V3R, V4R and V5R as the three lead axes to reflect the right ventricle with V1 lead as base point, and synchronous displaying of the six lead axes and 12 conventional lead axes. The expanded lead method of synchronous 21 leads includes back left deriving V7, V8 and V9 as the three lead axes on the basis of V5 lead axis. The lead method including converting the inclined angles in orthogonal electrocardiogram mode with right and left side correction and multiple bedding plane electrocardiogram lead containing up and down whole angles is the combined application of lateral electrocardiogram and transverse plane/frontal plane electrocardiogram.
Description
Technical field
The present invention relates to a kind of medical treatment method of leading of the electrocardiogram class detecting instrument of use clinically that is used for, especially a kind of in conjunction with the big hardware system of instrument heart tele-release, realize with the computer software method, very simple with the operation that method of mathematical derivation is derived out, only can obtain electrocardio and almost all lead with seven external electrodes, the bulk information amount change the multiple electrocardiogram method of leading in gauged orthogonal ECG mode.
Background technology
The technology of the present invention theoretical basis comes from electrocardial vector-electrocardio orthogonal ECG and clinical Electrocardiographic reprojection basic theories.
The theoretical basic theories that produces for electrocardiogram of electrocardio reprojection is the instructional theory that present electrocardiogram circle is used to explain the electrocardiogram generation.Its theoretical basis is approved by vast electrocardio circle expert, but really is not applied in the clinical use all the time.
Electrocardial vector orthogonal ECG and Electrocardiographic relation
Theoretically, Electrocardiographic generation is the result of electrocardial vector reprojection.And, having the pathological change of direction property electrocardio-activity for judgement, the three dimensions that especially embodies electrocardio-activity changes the characteristics aspect, and electrocardial vector has obvious superiority than routine electrocardiogram.Therefore in clinical practice for many years, electrocardial vector and electrocardiogram complement each other all the time, bring out the best in each other.
But electrocardial vector not exclusively is equal to electrocardiogram again, objective reality for various reasons, and the electrocardiogram of drawing out according to the vector diagram track, or directly draw by routine electrocardiogram between the vectorcardiogram that comes out and often exist than big-difference.As can be seen, explain that with electrocardial vector Electrocardiographic generation still has many incomplete places fully.Therefore some scholars think that the electrocardiogram of being calculated out by vectorcardiogram is that a kind of manually deriving is inaccurate fully, should not promote.But no matter be on point of theory, still from the actual clinical utilization, electrocardial vector and Electrocardiographic generation relation are inseparable, and vectorcardiogram and the orthogonal ECG that derives from thereof still are of great importance to clinical cardiac diagnosis.
One, the system kind of leading of electrocardial vector
(1) the system kind of leading: the kind of leading that the record electrocardial vector is used is a lot, drops into the not kind surplus in the of 20 down of using and having appeared in the newspapers and led, but the most common to have following several:
(1) equilateral four sides system (the Eqwilateral tetrahedrom system of Wilson Deng Shi, 1947.) being five electrode modes: this system supposition heart that leads is positioned at the center of triangle four limit bodies, this four limits body is equilateral, four drift angles are laid four electrodes, electrode 1-3 lays respectively at right arm (R), left arm (L) and left side foot (F), and common connection is central station (C).Electrode 4 is positioned at 2.0cm place (B), a seventh dorsal vertebra level left side, back, end points as four limit bodies, each electrode connect (I), be form: Y-axis is I by electrode 1-2, last lower shaft is that avf and antero posterior axis are three axis of leads of VB by electrode 4 and central station C by electrode 3-4, to show face amount (F), side (S) and three plane vector figure of plane of structure (H).
(2) GrishmanShi cube system (cube system, 1952) is five electrode modes: this system of leading also supposes that heart is positioned at a cubical center of square, and cube has eight drift angles, gets its four and lays electrode.Its method is: electrode 1-2 lays respectively at a left side and right posterior axillary line first (or second) lumbar vertebra level, and electrode 3 is positioned at right anterior axillary line first (or second) lumbar vertebra level, and electrode 4 is positioned at right posterior axillary line scapula top.Each electrode is connected and draws X-axis (trunnion axis is a Y-axis) and be made up of electrode 1-2, Y-axis (going up lower shaft) is made up of electrode 2-4, Z axle (antero posterior axis) is made up of electrode 2-3 and is constituted three axis of leads, in order to show face amount (F), side (S) and three plane electrocardial vectors of plane of structure (H).
(3) Schmitt-simonsonShi 14 electrode systems (14-Electrode or SVEC-IIIsystem, 1955.): its electrode 1-4 is positioned at the front quadrangle and becomes square, lay respectively at the inboard place of midclavicular line of left and right sides parasternal line the 3rd, six intercostal levels, electrode 5-8 is positioned at that to constitute square behind corresponding with front 1-4, electrode 9-10 is positioned at the left anterior axillary line of left side arm (or wrist) and parasternal line the 5th intercostal level, and electrode 11-12 is positioned at the corresponding offside of 9-10 electrode.Electrode 13 is positioned at left lower extremity, and electrode 14 is positioned at the right side cervical region.Each electrode forms X, Y, Z axle by resistor network, thereby produces face amount (F), side (S) and three plane vectorcardiograms of plane of structure (H).
(4) FrankShi seven electrodes system (the T-Electrode system that leads, 1956): wherein five electrodes are at thorax, be that electrode A-I lays respectively at left and right sides midaxillary line four-five intercostal levels, electrode E-M lays respectively at front median line and back midspinal line the four-five intercostal level, electrode C is miter angle part the four-five intercostal level between anterior midline and right midaxillary line, and the above intercostal level all is as the criterion with parasternal line (para-steraufline).All the other two electrodes are that H-F lays respectively at cervical region and left side foot.Each electrode forms X-axis (Y-axis is made up of the A-I electrode), Y-axis (going up lower shaft is made up of the H-F electrode) and three axis of leads of Z axle (antero posterior axis E-M electrode is formed) respectively by resistor network, in order to show face amount (F), side (S) and three plane vectorcardiograms of plane of structure (H).
(5) Mcfee-ParungaoShi axial system (axial system, 1961): with nine electrodes.Locate A-B 2 points earlier, wherein the A point is at the left breast parasternal line outside-centimetre the 5th intercostal level place, and the B point is positioned at and place, the same horizontal left anterior axillary line of A point, and electrode 1,2,3 is that the center is respectively apart from six centimetres of equilateral triangles that are arranged as the substrate infra of A point with the A point; Electrode 4 is positioned at back and front A point corresponding section; Electrode 5-6 at each apart from each 5.5 centimeters of B point upper and lower; Electrode 7 is positioned at and place, the corresponding right anterior axillary line of B point; Electrode 8-9 lays respectively at left lower extremity and left side cervical region.Constitute X, Y, three of Z and form face amount (F), side (S) and plane of structure (H) plane vectorcardiogram by resistor network between each electrode.
What deserves to be mentioned is, in recent years because the develop rapidly of dynamic electrocardiogram diagram technology.Multi-lead shows that synchronously the ambulatory electrocardiogram quasi-instrument steps into EGC detecting Instrument market gradually.Because classical static vector figure, ECG electrode is laid mode by traditional positions such as patient's limbs, cervical region that place.Obviously can not adapt to the requirement of ambulatory electrocardiogram quasi-instrument.Therefore for fear of the time body electrode since a large amount of artifacts that motion, myoelectricity, interference cause occur, on nearly all ambulatory electrocardiogram instrument, all electrodes that relates to limbs, the limb electrode position is improved without exception almost, generally electrode is moved to trunk, the concrete method that adopts often is: the upper limb electrode places near the bilateral shoulder nest position more, and lower limb electrode as many as has been obtained better effects in abdominal part.
(2) the lead selection of system:
We know that electrocardial vector projection result for the second time is that electrocardial vector finally produces electrocardiogram each bar axis of leads colonel shape.And the basis of the system of leading that electrocardial vector adopts must be to adopt orthogonal lead (orthogonallead), be that used three axis of leads are vertical mutually, with relative right angle intersection, it is axial to form X-axis (transverse axis), Y-axis (longitudinal axis) and three on Z axle (antero posterior axis) each other.
Owing to the actual asymmetry in the position of heart in torso model (be heart in the thoracic cavity, be not positioned at the center be positioned at the characteristics of thoracic cavity before taking back), be positioned at X, Y, the Z three that the pattern cube center calculated forms and axially lead if heart is designed to heart, obviously can not correctly reflect the feature of electrocardio-activity.
For this reason, many scholars adopt as increasing electrode or inserting resistance and build up methods such as resistor network from the fifties, and this is proofreaied and correct, and have produced diversified correction and have led (corrected orthogonal lead), and obtained effect preferably.According to this standard, aforesaid equilateral tetrahedron system and cube system belong to uncorrected orthogonal lead system, and 14 electrodes, Farnk seven electrode systems and nine electrode axis systems belong to the correction of orthogonal system of leading.
For the selection of the system of leading, we think should be to select for use gauged Frank orthogonal lead system for well, and main cause is that the figure that is write down can reflect the electrocardio-activity state more really, and with traditional routine electrocardiogram comparability is preferably arranged.In above-mentioned three correction of orthogonal led system, 14 electrode modes were too much because of electrode number, operation inconvenience, and 9 electrode axis system electrode riding positions are to women and unsuitable for children.At present both at home and abroad extensively the correction of orthogonal that the adopts system of leading mostly is the FrankShi system, calibrated FrankShi system is basic right angle intersection on electric physiology, and meet the Human Physiology anatomical features, the more relative coincidence rate with routine electrocardiogram of the electrocardiogram that the electrocardial vector that writes down out is extrapolated is higher, and electrode number is few relatively, easy to operate, also can obtain suitable electrode position to women, child.Be able to extensive use.
Two, the relation of vectorcardiogram electrocardiogram
As what everybody understood: from the vector diagram angle, the running orbit of interim everyone the moment resultant vector of electrocardiogram is noted down in chronological order and can be formed vector loop, but exist because this ring body is a three dimensions, can't correctly reflect vector loop running orbit strictly according to the facts with a plane.About traditional cardiovectograph is pressed this spatial vector loop (seeing figure) at any time, front and back, the various combination projection leads not that coplanar (quadrant) gets on up and down, face amount by about (X-axis) up and down (Y-axis) form the side by about before and after (Y-axis) (Z axle) forms, plane of structure by about before and after (X-axis) (Z axle) form and obtain the projected planform first time.Three plane graphs are corresponding to mutually drawing the 3 D stereo vectorcardiogram.
Figure slightly
Press the electrocardial vector notion,, can obtain alignment curve of different nature, in order to express electrocardio-activity-electrocardiogram, i.e. reprojection's process of electrocardio-activity projection on each comfortable corresponding axis of leads of plane vector ring (as face amount, plane of structure) of electrocardial vector.Otherwise the system ECG pattern of will respectively leading also can on the vector and coordinate of horizontal each face of side, be drawn corresponding vectorcardiogram with each wave group back projection of electrocardio to volume.Electrocardiogram with vector conversion can be divided into two big classes according to used axis of leads character: (1) orthogonal ECG: for about, up and down, projection on three the mutual right angle intersection axis of leads in front and back must X, Y, the Z lead electrocardiogram.Directly related with vectorcardiogram.(2) common clinical electrocardiogram: be projection on the face amount of stipulating, plane of structure axis of leads, each lead electrocardiogram also is called standard cardioelectric figure before obtaining the limbs and the heart, but the reflection to measure feature not as orthogonal ECG complete, though still can represent the amplitude size can not distinguish about, up and down, the fore-and-aft direction feature.What worth finger was same is: the electrocardiograph of clinical extensive employing at present is not according to the vector loop Projection Design, and amplify generation for directly adopting wilson body surface potential difference method to receive electrocardiosignal with external electrode, therefore clinical used electrocardiogram is compared relative less with the dependency of vector with orthogonal ECG.
Be illustrated from reprojection's angle below:
With H face vector loop is example explanation vector loop and two kinds of relations that electrocardiogram produces:
Horizontal vector loop-orthogonal ECG.
Frontal vector loop-orthogonal ECG.
Figure slightly
Three, orthogonal ECG and clinical Electrocardiographic relation
As noted earlier, in fact orthogonal ECG both had been a vectorcardigram, difference between the two only is that plane vector figure is with the running orbit journal of electrocardial vector on each quadrant, form the vector loop of XYZ three axial plane projections in the planar rings body by the spatial order projection, orthogonal ECG then is the curve that the running orbit of this electrocardial vector directly is scaled spoke degree/direction/time with three axis of leads of XYZ, poor than the plane vector chain rate than ring body form intuitive, also can obtain quantification notion and measured value but approach our the usual routine electrocardiogram of being familiar with very much.
If synchronous 12 lead above electrocardiogram by what the vector diagram of the FrankShi of standard noted down simultaneously that X, Y, Z three beam warp mathematical methods derive out, then have than big-difference with traditional routine electrocardiogram without proofreading and correct.At present, the general employing write down these three through angle and amplitude correction method to lead (is X, Y, Z) electrocardiogram is called orthogonal ECG, utilize preferably computational methods to proofread and correct, can reflect the movable practical situation of cardiac electrophysiology more truly, and will reduce to less, help comparison and clinical use with the difference of traditional routine electrocardiogram figure.
If limb lead adopts 90 degree three way classificatioies in the clinical Electrocardiographic axis of leads, precordial leads adopts 90 degree quarterings, orthogonal ECG X-axis waveform and the clinical electrocardiographic criteria of the representing Y-axis waveform similarity that leads that leads then, the avF waveform similarity that leads is gone up in the augmented unipolar limb lead of lower shaft in lead waveform and representative of Y-axis, on the Z spindle guide connection waveform initial design with commonly use electrocardiogram and do not have consistent leading, this be because classical FrankShi System Design Z axle be preceding negative after just, direction is just in time opposite with traditional electrocardio Figure 90 degree V2 of place axis of leads direction, after this many scholars are designing the vectorcardiogram type instrument for the ease of comparing with routine electrocardiogram, it is negative, then consistent with traditional electrocardiogram that the Z axle is designed to preceding positive back.
Our used orthogonal ECG adopts X, Y, three on Z axle to intersect at present, three's joining is the E point, vertical mutually for forming X-Y axle formation face amount (F), the X-Z axle constitutes plane of structure (H) and Y-Z axle structure side (S) is divided into left surface and right flank again, the positive-negative polarity direction is defined as previously mentioned on the Y-axis and is just bearing down, and the preceding positive back of Z axle is born, the left positive right side of X-axis is negative.
What be worth emphasizing is, because clinical Electrocardiographic three way classification and quartering are the electrocardio theoretical models for the ease of drawing projection and easy to understand vectorcardiogram and the setting of Electrocardiographic relation, be not by the human heart axis of leads system handled through overcorrect of physical location in vivo, as described in the relevant chapters and sections in front, from the clinical practice application point, have only the electrocardiogram (and through gauged axis of leads system) that changes through gauged X, Y, Z three axle center electrographs just can be converted to the more consistent electrocardiographic wave of comparatively real and traditional electrocardiogram.
Figure slightly
Theoretically, therefore the ecg wave form of orthogonal ECG conversion has certain difference owing to derive from electrocardial vector between the electrocardiogram that must consider vector generation electrocardiogram on the rudimentary algorithm and directly be produced by ecg signal amplifier.Only this be because electrocardial vector and axis of leads square be inverse ratio, with a heart beating, the projected size of same vector loop on different axis of leads often had any different.The angle and the size of electrocardial vector own between positive and negative, the axis of leads of axis of leads, the distance between the size of electrocardiographic wave and electrocardial vector and the axis of leads also has much relations.In general, electrocardial vector is from the distance and the proportional relation of electrocardio amplitude size of axis of leads.In theory: electrocardial vector between projected size on the axis of leads and this axis of leads and electrocardial vector distance square be inverse ratio.
Generally speaking, chest lead is centrifugal dirty nearer than limb lead, and we often can see that to be higher than the limb lead avR centroid that leads with precordial lead electrocardiogram voltage on the electrocardiographic wave dirty far away, and main ripple deviates from electrocardial vector principal direction, so amplitude is lower.And for example face amount QRS ripple maximum vector comparatively 60 the degree about electrocardial vector be principal direction, be 30 degree for the lead angle of formation of avR and avF, if say that with projection angle the two about equally merely, but the negative wave degree of depth that the R ripple of the actual avF lead electrocardiogram of measuring often leads apparently higher than avR, and for example we often can see the changeableness of lead electrocardiogram waveform ...Therefore in orthogonal ECG and the traditional Electrocardiographic relation (referring to graphic feature and amplitude) considering to produce by electrocardial vector.Below all being the influence factor, also is one of gauged factor in addition.
Because orthogonal ECG can directly derive out the multi-lead electrocardiographic wave with mathematical method again, this technology in recent years in the world some medical apparatus and instruments manufacturers made positive good try in this respect, and obtained certain effect.Since with this kind method on the one hand because the electrocardiogram that vector produces is subjected to factors such as whether proper some objective factors influences and computational methods employing, there is some difference with traditional electrocardiogram sometimes to produce electrocardiogram, thereby in clinical use, cause some scholars' dispute, but it is evident that if employing is also proofreaied and correct and the two difference can be reduced to less than good algorithm.And because this kind method adopts electrode few, interference artifact etc. can be effectively controlled, and advantages such as quick and easy to use, that instrument is inexpensive are relatively arranged.Say to a certain extent, can carry out certain qualitative and quantitative analysis to its electrocardiagraphic wave, can satisfy clinical use, therefore can yet be regarded as a kind of is to be suitable for the method for using as ambulatory electrocardiogram.
The Electrocardioscopy technology is a kind of technology that the electronic technology heart and brain bio electricity mv level signal that human body is faint amplifies and record comes out and analyzed of utilizing, electrocardiogram is applied to a clinical existing one-hundred-year history from invention, year history surplus the application of ambulatory electrocardiogram also has 40.
Because the electrocardiogram detection technique is actually a kind of electrocardio potential difference detection technique, heart is the extremely complicated 3D solid organ of a structure, the viewpoint human body of learning according to electrocardial vector each electrocardio floats all and to produce in the continuous form with moment vector moment, its direction and strength finally each moment little consent vector countervailed, and represent each instantaneous maximum vector to represent the trend of heart complex electrocardio vector.Be reflected in electrocardiogram and promptly produced corresponding potential difference change.Because in this three-dimensional organ of heart, various and reason and pathological factor be to the influence of heart, and the variation of electrocardial vector greatly (has very big difference to show as electrocardiogram as variant instantaneous resultant vector direction amplitude and leads respectively that to go up waveform very different).In order to fully understand and write down the electrocardio situation of change, instrument must be from each angle, each orientation detection electrocardio comprehensive condition, and Here it is refers to set lead system on the clinical electrocardiograph.
In fact the development history of ECG lead systems has run through the whole process of whole electrocardio detection technique development history, having only a unit to lead from Entovtn invention electrocardiogram leads to a two-shipper, add that to developing into avR, avL, avF, V1-V6 are at interior twelve-lead electrocardiogram, experienced very long process decades, ambulatory electrocardiogram also so from singly lead-two leading-three lead up-to-date 12 lead electrocardiogram, as if the 12 lead electrocardiogram represented present Electrocardiographic standard detection level.
12 lead electrocardiogram (containing ambulatory electrocardiogram) refers to and comprises three of I, II, III system (liking the system of leading that Yin Shi uses the earliest) when bipolar, avR, avL, three one pole augmented limb leads of avF and six chest leads of V1-V6, basically can reflect the unsteady situation of the most electricity of heart, situations such as myocardial ischemia, damage necrosis are needed observe variations such as 3T section, T ripple on electrocardiogram.I.avL.V6 leads and can reflect right ventricle sidewall situation, and II.III.avF leads and can reflect left ventricle lower wall situation; V4, V5, V6 lead and can reflect left ventricle antetheca situation, and V1, V2, V3 lead and can reflect chamber, left and right sides interventricular septum situation.These four position electrocardiogram situations, the 12 lead technology can write down out with synchronous versions at present.But also have following problem: 1) heart also has positive rear wall in left chamber and right ventricle, leads with V7, V8, V9 respectively and V3R-V4R, the V5R reflection of leading, and can't accomplish when above 12 lead detects; Standing procedure is to be to take turns doing out that V7-V9 leads or V4, V5, three ball electrodes of V6 are posted once more again successively after finishing twelve-lead electrocardiogram and trace front V6 crosslinking electrode is right-hand left with the positive rear wall situation of left ventricle, desire to trace the right ventricle situation, be the V1 electrode to be pasted again to the right back successively again trace after the right back is traced out V3R-V5R successively or V1, V2, three electrodes of V3 are being finished twelve-lead electrocardiogram, the problem that such operational approach exists is: 1. operation is extremely loaded down with trivial details bothersome; 2. can't accomplish with twelve-lead electrocardiogram synchronous at all; 3. owing to there is several electrodes rearward, especially can not move patient during heart infarction, the operator position disunity of at every turn having an electro-cardiogram is operated and is caused each figure inconsistent when lack of standardization, obvious distortion occurs.
2) when some clinical situations that are not true to type of running into sometimes, especially when atypical angina pectoris or little focal myocardial infarction, can't record the pathologic electrocardiographic wave in the used conventional 4-5 intercostal horizontal level electrocardioelectrode of electrocardiogram, at this moment, operator need that front electrode used therein (V1-V6 or V1-V9 add V3R-V5R) is moved one up or down simultaneously and have an electro-cardiogram again to one and half intercostals, its trouble degree is well imagined, and also as easy as rolling off a log (position is inaccurate) lack of standardization because of operating brings the electrocardiagraphic wave distortion.
3) existing research data shows: when some myocardium of right ventricle infarction, leading at traditional V3R-V5R can not show typical cardiac electrical figure fully and change, and need be V6R even the V7R-V8R electrocardiogram can; This moment, operator need will repeat 1 with V1 electrode or V1-V3 electricity) described in method, continue to the right back traveling electrode, and trace again, its shortcoming is apparent.
Summary of the invention
The objective of the invention is deficiency, a kind of multiple synchronous electrocardiogram lead method of changing in gauged orthogonal ECG mode is provided, only just can obtain multiple synchronous electrocardiogram with seven electrode shirtsleeve operations at above-mentioned 12 lead electrocardiogram.
For achieving the above object, solution of the present invention is: a kind ofly change the multiple electrocardiogram method of leading in gauged orthogonal ECG mode, be Frank (Frank) family name seven electrodes systems of leading, its synchronous twelve-lead electrocardiogram comprises three bipolar limb leads of face amount I, II, III that the X-Y axle constitutes, avR, avL, three one pole augmented limb leads of avF, and six chest leads of plane of structure V1-V6 of X-Z axle formation, it is characterized in that theory, utilize the ambulatory electrocardiogram detector to realize the following multiple electrocardiogram method of leading according to electrocardio reprojection:
The method of leading of synchronous 18 lead electrocardiogram of changing in gauged orthogonal ECG mode;
With gauged orthogonal ECG mode change in synchronous 18 synchronous 21 methods of leading of leading of leading and expanding on the basis;
Each angle of inclination stage construction electrocardiogram lead method of changing in the gauged orthogonal ECG mode in the side that comprises the and arranged on left and right sides face.
The method of leading of described synchronous 18 lead electrocardiogram of changing in gauged orthogonal ECG mode is that to lead with V6 be basic point, to the left back to the axis of leads of deriving out the positive rear wall of V7, V8, V9 three reflections left ventricle, and to lead with V1 be the axis of leads that basic point continues to derive out V3R, V4R, three reflections of V5R right ventricle to the right, and above-mentioned six axis of leads and conventional 12 lead axle are shown synchronously and constitute synchronous 18 lead electrocardiogram jointly.
Described with gauged orthogonal ECG mode change in synchronous 18 synchronous 21 methods of leading of leading of leading and expanding on the basis, be on the basis of V5 axis of leads, to the right back derive out V6R, V7R, three axis of leads of V8R and with synchronous 18 lead and constitute synchronous 21 and lead jointly, its three angles that axis of leads is got are arbitrarily angled between 180 °-270 ° of plane of structures.
Described to comprise a left side, each angle of inclination stage construction electrocardiogram lead method that the gauged orthogonal ECG mode in side of right two sides is changed, be side electrocardiogram and plane of structure, face amount combines synchronous 18 leads and the combination of synchronous 21 lead electrocardiogram, it is the multiple coupling method of extrapolating by seven electrodes of body surface that leads in several planes, each angle of inclination of this side orthogonal ECG conversion is to contain arbitrarily angled within the full angle that moves and move down and the scope thereof, the build that the size of its move angle is different with human body, fat or thin, the thorax size, the intercostal space size adapts.
After adopting such scheme, the present invention compared with prior art has following beneficial effect: the present invention is owing to be foundation with electrocardio reprojection theory, utilized serial ambulatory electrocardiogram detector to realize the multiple electrocardiogram method of leading, overcome the deficiencies in the prior art, only just can satisfy clinically needs fully comprehensive observation heart ECG change with the simple operations of seven electrodes.The characteristics of the method for leading of synchronous 18 lead electrocardiogram that it is changed in gauged orthogonal ECG mode are:
Synchronous 18 lead electrocardiogram that this is traced synchronously comprise conventional 12 lead and lead with the V3R-V5R and six of the V7-V9 that increase newly, have contained to comprise the electrocardio-activity detection comprehensively of left and right sides chamber cardiac muscle.
These synchronous 18 lead electrocardiogram are more basic identical through clinical trial in enormous quantities and traditional method routine electrocardiogram, and the distortion factor is less, meets clinical use standard.
By using synchronous 18 lead electrocardiogram analyses, can understand the electrocardio-activity at each position of heart, especially fully understand the ischemic ECG change of different parts locular wall.Newly-increased V3R-V5R, six of V7-V9 lead and can effectively detect positive rear wall in left chamber and the right ventricle situation that conventional 12 lead is difficult to check, and the detection of ischemia, damage even the downright bad sample ECG change that these positions cardiac muscles are occurred has special meaning; II, III, aVF lead to the detection of contrary property P ripple, help the affirmation to the junctional area rhythm of the heart.
Synchronous 18 lead electrocardiogram on this instrument only with 7 few electrodes of number trace out number nearly 18 lead, can cover each face of cardiac muscle, number of electrodes is few, simple to operate and range of observation big, it is comprehensive to diagnose.
Should with gauged orthogonal ECG mode change in synchronous 18 synchronous 21 methods of leading of leading of leading and expanding on the basis, its V6R that derives out, V7R, three axis of leads of V8R do not need operator to operate loaded down with trivial detailsly and have solved the detection problem of right ventricle more easily.
Be somebody's turn to do each angle of inclination stage construction electrocardiogram lead method of changing in the gauged orthogonal ECG mode in side, because it leads with synchronous 18 and 21 of plane of structure, face amount and combines application, convenient and effectively solved the detection problem of some special mess myocardial damages, necrosis or atypical myocardial necrosis, damage, do not need by utmost point complicated operations, all precordial electrodes are raised or reduced 1-2 intercostal and solve.
Below in conjunction with accompanying drawing the specific embodiment of the present invention is described in further detail.
Description of drawings
Fig. 1 is a prior art face amount electrocardiogram lead axle;
Fig. 2 is a prior art plane of structure electrocardiogram lead axle;
Fig. 3 is that the multiple synchronous electrocardiogram lead method that the present invention changes in gauged orthogonal ECG mode expands to the 18 plane of structure electrocardiogram lead axles that lead;
Fig. 4 is that the multiple synchronous electrocardiogram lead method plane of structure electrocardiogram lead axle that the present invention changes in gauged orthogonal ECG mode is derived out V6R-V8R;
Fig. 5 is the multiple synchronous electrocardiogram lead method left surface electrocardiogram lead axle that the present invention changes in gauged orthogonal ECG mode;
Fig. 6 is the V2 axis of leads that an intercostal was raised/reduced to multiple synchronous electrocardiogram lead method that the present invention changes in gauged orthogonal ECG mode;
Fig. 7 is the multiple synchronous electrocardiogram lead method left surface electrocardiogram lead axle that the present invention changes in gauged orthogonal ECG mode;
Fig. 8 is the multiple synchronous electrocardiogram lead method plane of structure electrocardiogram lead axle distribution signal that the present invention changes in gauged orthogonal ECG mode;
Fig. 9 is that the multiple synchronous electrocardiogram lead method plane of structure that the present invention changes in gauged orthogonal ECG mode reduces by 30 ° of cardiac diagnosis lead axles distribution signals;
Figure 10 is the multiple synchronous electrocardiogram lead method that the present invention changes in gauged orthogonal ECG mode, from the clinical Electrocardiographic concrete steps figure of orthogonal ECG projection;
Wherein: Figure 10 .1 is former figure;
Figure 10 .2 is an enlarged drawing;
Figure 10 .3 is tabulation for the first time, and X, Y, Z amplitude are mm;
Figure 10 .4A is for setting the limb lead of clinical each axis of leads of electrocardiogram, with 90 ° of angles, three equal point-scores;
Figure 10 .4B is for setting the precordial leads of clinical each axis of leads of electrocardiogram, with 90 ° of angles, four equal point-scores;
Figure 10 .5A leads to II for to be projected to clinical Electrocardiographic each axis of leads with X, Y, Z range value
The figure of axial projection;
Figure 10 .5B leads to III for to be projected to clinical Electrocardiographic each axis of leads with X, Y, Z range value
The figure of axial projection;
Figure 10 .5C leads to V1 for to be projected to clinical Electrocardiographic each axis of leads with X, Y, Z range value
The shaft coupling projection;
Figure 10 .5D leads to V5 for to be projected to clinical Electrocardiographic each axis of leads with X, Y, Z range value
The shaft coupling projection;
Figure 10 .6 is tabulation for the second time: some preface 8 amplitudes are the measured value of legend, and other preface amplitudes are
Insert after the measurement;
Figure 10 .7 is for becoming figure;
Figure 10 .8 is for dwindling figure.
The specific embodiment
The present invention changes the multiple electrocardiogram method of leading in gauged orthogonal ECG mode, it is Frank (Frank) family name electrode system of leading, be on the basis of present existing 12 lead, utilize the electrocardial vector principle, the multiple electrocardiogram method of leading is derived in utilization orthogonal ECG projection.As depicted in figs. 1 and 2, the plane of structure electrocardiogram lead axle that the face amount that the X-Y axle constitutes, X-Z axle constitute, it is the situation of leading of present 12 lead electrocardiogram, it comprises I, II, three bipolar limb leads of III, avR, avL, three one pole augmented limb leads of avF, and six chest leads of V1-V6.Shown in Fig. 3,4,5,6,7,8,9, on the basis of 12 lead,, utilize the ambulatory electrocardiogram detector according to electrocardio reprojection theory, present embodiment is to utilize BETHUNE-21 series ambulatory electrocardiogram detector to realize the multiple electrocardiogram of the present invention method of leading, and this method is:
First, the method of leading of synchronous 18 lead electrocardiogram of changing in gauged orthogonal ECG mode, be that to lead with existing V6 be basic point, to the left back to the axis of leads of deriving out three reflections of V7, V8, V9 left ventricular posterior wall, and to lead with V1 be the axis of leads that basic point continues to derive out V3R, V4R, three reflections of V5R right ventricle to the right, and above-mentioned six axis of leads and conventional 12 lead axle are shown synchronously and constitute synchronous 18 lead electrocardiogram jointly.
The second, with gauged orthogonal ECG mode change in 18 synchronous 21 methods of leading of leading of leading and expanding on the basis, be on the basis of V5 axis of leads, to the right back derive out V6R, V7R, three axis of leads of V8R and with synchronous 18 lead and constitute synchronous 21 and lead jointly, the angle that its three axis of leads are got is arbitrarily angled between 180 °-270 ° of plane of structures, and this V6R, V7R, three axis of leads of V8R have bigger meaning to the detection of right ventricle.
Three, each angle of inclination stage construction electrocardiogram lead method of changing in the gauged orthogonal ECG mode in the side that comprises the and arranged on left and right sides face.The face amount that the above system of leading that is converted by gauged orthogonal ECG is made up of the X-Y axle is that plane of structure that F face and X-Z axle are formed is that the H face combines 18 and the 21 lead electrocardiogram, the basic horizontal standard is pressed the international uniform standard in the four-five intercostal level, and this kind method can solve the electrocardiogram detection of most of ECG change clinically.But as described in preceding relevant part, downright bad or when not being true to type the myocardial necrosis damage at the special mess myocardial damage, clinical normal need are raised all electrodes or are reduced certain level when record, just relatively more difficult, must all precordial electrodes be raised or reduce 1-2 intercostal and can solve by utmost point complicated operations.
According to this point, it is that to contain a left side be LS to S face (orthogonal ECG) that this method propose to be utilized the side electrocardiogram that is not exploited as yet, the right side is that two sides of RS address this problem, this method is side electrocardiogram and plane of structure, face amount combines synchronous 18 lead and synchronous 21 lead electrocardiogram in conjunction with using, it is the multiple coupling method of extrapolating by seven electrodes of body surface that leads in several planes, each angle of inclination of this side orthogonal ECG conversion is to contain arbitrarily angled within the full angle that moves and move down and the scope thereof, the build that the size of its move angle is different with human body, fat or thin, the thorax size, the intercostal space size adapts.
Illustrate with left surface, distribute according to quadrant on the left surface that is made of Y-Z: the shirtfront side is represented in the left side, and posterior dorsal is represented on the right side, and the top side is gone up in the top representative, and the below representative is sufficient side down.On the Z axle, represent anterior electrocardiographic lead 4-5 rib level for 0 °-180 °, 0 ° of representative-V2 wherein, 180 ° of representative+V2,90 ° of representative+avF, 270 ° of representative-avF.
When needs are done a last rib or next rib electrocardiogram, with V2 is that example can be raised the V2 axle or the certain angle that descends for 0 °-180 ° on left surface, with 30 ° is example, then obtain raising 30 ° V2 or 30 ° the V2 (seeing Fig. 5,6,7,8,9) of descending, promptly be equivalent to next rib electrocardiogram lead of a rib.
Move or descend 30 ° or other angles on (each axis of leads of available medial surface-face amount is the plane) different angles value and this axle when the method is applied to 0 ° of-180 ° of level of each axis of leads of front, then can try to achieve a front last rib/next the rib electrocardiogram lead axle that respectively leads.
On/following moving range can be set in, on move 180 °-270 °, move down between 180 °-90 °.
This kind method is still carried out with method of mathematical derivation, the different angle joints that are to calculate plane of structure and two axles of side-face amount with simple 18 lead electrocardiogram.
Can extrapolate the multiple connecting mode that leads in several planes by seven electrodes of body surface with the method, can be described as holographic formula or true three-dimensional electrocardiogram.
Reach the multiple synchronous electrocardiogram lead method of changing in gauged orthogonal ECG mode according to aforementioned principles, to respectively leading after on three of F, H, the S axis of leads being carried out certain angle/adjustment factor adjustment and proofreading and correct, carry out axis of leads electrocardiogram value and calculate, its computational methods are as follows:
From the clinical electrocardiogram of orthogonal ECG projection.
Clinical electrocardiogram also can obtain as described above from the vectorcardiogram projection except that directly tracing with electrocardiograph, and the projection of available orthogonal electrocardiogram.Otherwise clinical electrocardiogram also projectable is an orthogonal ECG.Projection more belonged to mutual projection (reciprocal projection) between two kinds of different electrocardiograms were mutual.It is many with Jia Zhi Utah wherein orthogonal ECG to be projected as clinical Electrocardiographic Shi, and for example above-mentioned 18 ambulatory electrocardiograms of developing (Holter) that lead are promptly used this method, trace out majority and synchronous electrocardiogram with the minority external electrode.
Use moment current potential (instantaneous potential) from the clinical electrocardiogram of orthogonal ECG projective rendering, its concrete steps are as follows, and referring to Figure 10, this figure explains: each figure top numeral of (1) orthogonal ECG is some preface (time), and the left side numeral is an amplitude.Amplitude is depicted as ratio value, and actual measurement can be scaled mm or ml.(2) Freehandhand-drawing of electrocardiogram lead axle equisection method is easy, can be used for telling about and understanding.Should select the axis of leads of proofreading and correct or giving suitable adjustment for use for projection more accurately.
1, referring to Figure 10 .1,10.2,10.3, amplify and tabulation: time and amplitude that orthogonal ECG X, Y, Z lead in elder generation, do suitably to amplify so that observation is prepared against projection with X, Y, Z current potential (amplitude) list records of each moment then.At this is example with the QRS wave group all.
2, set clinical Electrocardiographic axis of leads: in order to draw, to tell about and understanding conveniently, use the axis of leads equisection method to get final product, limb lead is divided equally for per 90 ° three, 30 ° of the spacings of leading; Precordial leads is divided equally for per 90 ° four, 22.5 ° of the spacings of leading.But, then should select for use and proofread and correct or axis of leads (consulting Figure 10 .4A and 10.4B) through suitably adjusting if require projection result more accurate.
3, projection: with observational record to the current potential amplitude upright projection of X, Y, Z each moment to clinical Electrocardiographic each axis of leads, as Figure 10 .5A, 10.5B is shown in 10.5C and the 10.5D.
Explain among the figure: numeral is the some preface on the vector loop, and each figure is an example with a preface 8 (0.04 second time) all, and other can imitate this.
The a=X range value (F, H face be all+X ,-X), i.e. numerical value on transverse axis.
(a)=the a value is in the vertical projecting line of transverse axis.
B=Y or Z range value (the F face is+Y ,-Y, the H face is+Z ,-Z), i.e. numerical value on the longitudinal axis.
(b)=the b value is in the vertical projecting line of the longitudinal axis.
C=constitutes tetragonal diagonal by a, b, and its end is the plotted point of (a) and (b).
D=is by the vertical projecting line of diagonal c end (the real preface place of promptly putting) to set axis of leads.
4, calculate: calculate the projection gained range value of each moment on each axis of leads; Can select the direct method of measurement or trigonometric function computing method for use.The former is simple and practical, and the latter is more complicated, but more accurate, and the two can cross reference.
I, the direct method of measurement:
(1) range value of X, Y, Z each point preface (time) is made upright projection respectively on the horizontal stroke of right angle intersection, the longitudinal axis, dotted line (a) and (b) in promptly scheming, limb lead X, Y-axis, precordial leads X, Z axle, Figure 10 .5A, B, each illustration of C, D are example with a preface 8 (0.04 second time) all;
(2) make upright projection (i.e. dotted line d in the figure) from the plotted point (actual point preface) of three projection line (a) and (b) to set axis of leads (angle is known, and for example equisection method II leads at+60 °, and V5 leads at+22.5 °).
(3) range value (E) of gained after the measurement projection.This can directly observe the amplitude of indicating on the axis of leads, or measures with gage and two limb dividers, draws the range value of being asked at last.If desire the angle measurement degree, available quantity hornwork (half-round compasses).
II, trigonometric function computing method: be example with Figure 10 .5A, B, C, D point preface 8 still, other prefaces are imitated this.
(1), (2) step and the direct method of measurement (1), (2) are identical.
(3) paint C line and θ, β, α angle: 1. C line: (a) and (b) form tetragonal diagonal; 2. θ angle: the angle between diagonal C and the transverse axis, enable the longitudinal axis and can remember with θ '.3. β angle, the angle between set axis of leads and the transverse axis is enabled the longitudinal axis and can be remembered with β '.4. α angle: the angle between set axis of leads and the diagonal C.
(4) ask C value and θ, β, α angle value: 1. C=(a
2+ b
2)
1/22. θ angle: tan θ=opposite side b/ opposite side a, must the θ angle value to remove the long-pending trigonometric table (or use electronic calculator) of looking into.3. β angle: the angle of set axis of leads is known, calculates the angle of measuring between itself and the transverse axis.4. α angle: α=β ± θ, in the formula ± decide on the position at painting β and θ angle.
(5) ask cos α value: look into trigonometric table (or using electronic calculator) with the α angle value, get cos αHan Shuo value.
(6) asking E value: E is dotted line d (being the vertical projecting line of diagonal C to axis of leads) range value of gained after set axis of leads projection.
∵ cos α=adjacent side E/ hypotenuse C
∴ E=C * cos α=(a
2+ b
2)
1/2* cos αHan Shuo value
The E value the positive side (+) of set axis of leads be on the occasion of, then be negative value at minus side (-).
5, tabulation again: each point preface (moment) in the range value E of measurement that set axis of leads calculates list records, is consulted Figure 10 .6.
6, draw: draw the figure that clinical electrocardiogram respectively leads, can be earlier with according to measuring, calculate and the range value that respectively leads (E) of record being painted in the electrocardiograph paper that all amplifies to amplitude and time, referring to Figure 10 .7.Then it is suitably dwindled, promptly get the clinical electrocardiogram that respectively leads after the projection, consult Figure 10 .8.
Above-mentioned various projections all are to be example with QRS ripple (ring), projection for wave bands such as P, ST, T, U, all can copy and carry out, constitute the transformation of the different expression-forms of complete electrocardio-activity, in addition, above-mentioned various projections are all carried out by hand for projection process is described, are aided with electronic calculator during calculating.If use microcomputer (computer, electronic computer) measurements and calculations, comprise software processes programs such as A/D (mould/number) and D/A (D/A) conversion, then can increase density measurement and (shorten time interval, increase some somes prefaces), accelerate arithmetic speed (to each angle, each amplitude and trigonometric function calculating and figure etc.), thus the more accurate again fast projection result that obtains.
Explain:
The △ angle: this diagram is indicated, for the known angle of set axis of leads, uses equisection method, 30 ° at the every interval of limb lead, 22.5 ° at the every interval of precordial leads.
The θ angle: the angle between diagonal C and the transverse axis, if can be made as θ ' with the longitudinal axis
α angle: the angle between set axis of leads and the diagonal C
The β angle: the angle between set axis of leads and the transverse axis, if can be designated as β ' with the longitudinal axis
The E value: the diagonal C-terminal is at the range value of set axis of leads upslide movie queen gained.
(6) calculated example: calculating with the trigonometric function method, is example with QRS/Q point preface 8, consults above-mentioned from the clinical Electrocardiographic character narrate of orthogonal ECG projection.
Figure 10 .5A, the range value of asking II to lead from orthogonal ECG.
1. the X value a=8.0 that leads, the Y value b=8.2 (in mm, below herewith) that leads.
②C=(a
2+b
2)
1/2=(8
2+8.2
2)
1/2=(131.24)
1/2=11.46
3. tan θ=opposite side b/ adjacent side a=8.2/8=1.23, (or using computer) θ=45.8 ° of tabling look-up
4. angle=90 of β angle=90 °-II axis of leads and Y-axis are °-30 °=60 °
5. α angle=β-θ=60 are °-45.8 °=14.2 °
6. cos α=cos14.2 °, (or the using computer) cos14.2 °=0.97 of tabling look-up
⑦E=C×cosα=(a
2+b
2)
1/2×cos14.2°=11.46×0.97=11.11
E the positive side of II axis of leads be on the occasion of, this promptly puts the range value of preface 8 in the projection of II axis of leads.
Figure 10 .5B, the range value of asking III to lead from orthogonal ECG.
1., 2., 3. with illustration A 1., 2., 3.
4. angle=90 of β angle=90 °+III axis of leads and Y-axis °+30 °=120 °
5. α angle=β-θ=120 are °-45.8 °=74.2 °
6. cos α=cos74.2 °, (or the using computer) cos74.2 °=0.27 of tabling look-up
⑦E=C×cosα=(a
2+b
2)
1/2×cos74.2°=11.46×0.27=3.09
E the positive side of III axis of leads be on the occasion of, this promptly puts the range value of preface 8 in the projection of III axis of leads.
Figure 10 .5C, the range value of asking V1 to lead from orthogonal ECG.
1. the X value a=8.0 that leads, the Z value b=1.8 that leads
②C=(a
2+b
2)
1/2=(8
2+1.8
2)
1/2=(69.24)
1/2=8.2
3. tan θ=opposite side b/ adjacent side a=1.8/8=0.225, (or using computer) θ=12.68 ° of tabling look-up
4. angle=90 of β angle=90 °-V1 axis of leads and Z axle are °-22.5 °=67.5 °
5. α angle=β-θ=67.5 are °-12.68 °=54.82 °
6. cos α=cos54.82 °, (or the using computer) cos54.82 °=0.576 of tabling look-up
⑦E=C×cosα=(a
2+b
2)
1/2×cos54.82°=8.2×0.576=4.72
E the minus side of V1 axis of leads be on the occasion of, this promptly puts the range value of preface 8 in the projection of V1 axis of leads.
Figure 10 .5D, the range value of asking V5 to lead from orthogonal ECG.
1., 2., 3. with illustration C 1., 2., 3.
4. angle=90 of β angle=90 °-V5 axis of leads and Z axle are °-67.5 °=22.5 °
5. α angle=β+θ=22.5 °+12.68=35.18 °
6. cos α=cos35.18 °, (or the using computer) cos35.18 °=0.817 of tabling look-up
⑦E=C×cosα=(a
2+b
2)
1/2×cos35.18°=8.2×0.817=6.7
E the positive side of V5 axis of leads be on the occasion of, this promptly puts the range value of preface 8 in the projection of V5 axis of leads.
Claims (4)
1, a kind ofly changes the multiple electrocardiogram method of leading in gauged orthogonal ECG mode, be Frank (Frank) family name seven electrodes systems of leading, its synchronous twelve-lead electrocardiogram comprises three bipolar limb leads of face amount I, II, III that the X-Y axle constitutes, avR, avL, three one pole augmented limb leads of avF, and six chest leads of plane of structure V1-V6 of X-Z axle formation, it is characterized in that theory, utilize the ambulatory electrocardiogram detector to realize the following multiple electrocardiogram method of leading according to electrocardio reprojection:
The method of leading of synchronous 18 lead electrocardiogram of changing in gauged orthogonal ECG mode;
With gauged orthogonal ECG mode change in synchronous 18 synchronous 21 methods of leading of leading of leading and expanding on the basis;
Each angle of inclination stage construction electrocardiogram lead method of changing in the gauged orthogonal ECG mode in the side that comprises the and arranged on left and right sides face.
2, according to claim 1ly a kind ofly change the multiple electrocardiogram method of leading in gauged orthogonal ECG mode, it is characterized in that: the method for leading of described synchronous 18 lead electrocardiogram of changing in gauged orthogonal ECG mode is that to lead with V6 be basic point, to the left back to deriving out V7, V8, the axis of leads of the positive rear wall of V9 three reflections left ventricle, and to lead with V1 be that basic point continues to derive out V3R to the right, V4R, the axis of leads of three reflections of V5R right ventricle, and make above-mentioned six axis of leads constitute synchronous 18 lead electrocardiogram jointly with conventional 12 lead axle demonstration synchronously.
3, according to claim 1ly a kind ofly change the multiple electrocardiogram method of leading in gauged orthogonal ECG mode, it is characterized in that: described with gauged orthogonal ECG mode change in synchronous 18 synchronous 21 methods of leading of leading of leading and expanding on the basis, be on the basis of V5R axis of leads, to the right back derive out V6R, V7R, three axis of leads of V8R and with synchronous 18 lead and constitute synchronous 21 and lead jointly, its three angles that axis of leads is got are arbitrarily angled between 180 °-270 ° of plane of structures.
4, according to claim 1ly a kind ofly change the multiple electrocardiogram method of leading in gauged orthogonal ECG mode, it is characterized in that: described to comprise a left side, each angle of inclination stage construction electrocardiogram lead method that the gauged orthogonal ECG mode in side of right two sides is changed, be side electrocardiogram and plane of structure, face amount combines synchronous 18 leads and the combination of synchronous 21 lead electrocardiogram, it is the multiple coupling method of extrapolating by seven electrodes of body surface that leads in several planes, each angle of inclination of this side orthogonal ECG conversion is to contain arbitrarily angled within the full angle that moves and move down and the scope thereof, the build that the size of its move angle is different with human body, fat or thin, the thorax size, the intercostal space size adapts.
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CN113208599B (en) * | 2021-05-17 | 2024-02-27 | 北京蓬阳丰业科技有限公司 | Method and equipment for pushing lead V3R, V R based on electrocardio monopole leads V1 and V5R |
CN117100283A (en) * | 2023-07-26 | 2023-11-24 | 兴化市人民医院 | Twelve-lead electrocardiogram generation method and device |
CN117100283B (en) * | 2023-07-26 | 2024-05-03 | 兴化市人民医院 | Twelve-lead electrocardiogram generation method and device |
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