CN110811597A - Electrocardiogram recording method, electrocardiogram recorder, electrocardiogram recording device and electrocardiogram recording medium - Google Patents
Electrocardiogram recording method, electrocardiogram recorder, electrocardiogram recording device and electrocardiogram recording medium Download PDFInfo
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Abstract
The application relates to an electrocardiogram recording method, which comprises the steps of obtaining left atrium electrocardiogram data acquired through left atrium leads and obtaining right atrium electrocardiogram data acquired through right atrium leads; trend analysis is respectively carried out on the electrocardiogram data of the left atrium and the electrocardiogram data of the right atrium, and when abnormal trends are obtained through analysis, electrocardiogram fragments corresponding to the abnormal trends are marked; respectively extracting a left atrium abnormal electrocardiogram fragment corresponding to the left atrium and a right atrium abnormal electrocardiogram fragment corresponding to the right atrium according to the marking result; and determining the abnormal type according to the abnormal electrocardiogram fragment of the left atrium and the abnormal electrocardiogram fragment of the right atrium. By performing trend analysis on the electrocardiogram data, marking electrocardiogram fragments corresponding to abnormal trends obtained by analysis, and determining abnormal types according to the marked abnormal electrocardiogram fragments of the left atrium and the right atrium, the right atrium and the left atrium can be accurately judged in priority. Furthermore, an electrocardiographic recorder, a device and a storage medium are proposed.
Description
Technical Field
The present invention relates to the medical field, and in particular, to an electrocardiogram recording method, an electrocardiogram recorder, an electrocardiogram recording apparatus, and an electrocardiogram recording apparatus storage medium.
Background
Electrocardiography (ECG or EKG) is a technique that uses an electrocardiograph to record a pattern of changes in electrical activity produced by each cardiac cycle of the heart from the body surface. Valuable clinical data can be obtained through analysis of the electrocardiogram, so that doctors are effectively assisted in diagnosis and treatment. However, the electrocardiogram recorded in the prior art is easy to generate the condition of 'missed' diagnosis in the non-attack period, so that the prior judgment of the left and right atrial waves cannot be accurately carried out, and an effective preoperative preliminary examination result cannot be obtained.
Disclosure of Invention
Based on this, the embodiments of the present invention provide an electrocardiogram recording method, an apparatus, a device, a computer device, and a storage medium, which can accurately determine the priority of the left and right atrial waves.
A method of electrocardiographic recording, the method comprising:
acquiring left atrial electrocardiogram data acquired through left atrial leads and right atrial electrocardiogram data acquired through right atrial leads;
trend analysis is respectively carried out on the electrocardiogram data of the left atrium and the electrocardiogram data of the right atrium, and when abnormal trends are obtained through analysis, electrocardiogram fragments corresponding to the abnormal trends are marked;
respectively extracting a left atrium abnormal electrocardiogram fragment corresponding to the left atrium and a right atrium abnormal electrocardiogram fragment corresponding to the right atrium according to the marking result;
and determining the abnormal type according to the abnormal electrocardiogram fragment of the left atrium and the abnormal electrocardiogram fragment of the right atrium.
In one embodiment, the determining the type of abnormality from the left atrial abnormal electrocardiogram fragment and the right atrial abnormal electrocardiogram fragment comprises:
acquiring a preset wave pattern, and acquiring the marking start time of the abnormal left atrium electrocardiogram fragment and the abnormal right atrium electrocardiogram fragment in the marking result;
and determining the type of the abnormity according to the preset wave pattern and the mark starting time.
In one embodiment, the determining the type of anomaly from the preset waveform and the mark start time includes: after the marking start time, acquiring the occurrence time of the preset wave pattern of each of the left atrial abnormal electrocardiogram fragments and the right atrial abnormal electrocardiogram fragments, sequencing the obtained occurrence time, and determining the occurrence sequence of the wave patterns in all abnormal electrocardiogram fragments according to the sequencing; when the abnormal left atrium electrocardiogram fragment appears in the preset wave pattern first, determining the abnormal left atrium electrocardiogram fragment as a first abnormal type; when the preset waveform appears in the right atrial abnormal electrocardiogram fragment first, determining the right atrial abnormal electrocardiogram fragment as a second abnormal type; and when the preset waveforms simultaneously appear, determining the abnormal left atrium and the abnormal right atrium as a third abnormal type.
In one embodiment, the trend analysis comprises: analyzing heart rate trend, ST-segment displacement trend and arrhythmia event frequency trend; the trend analysis is performed on the left atrial electrocardiogram data and the right atrial electrocardiogram data respectively, and when abnormal trends are obtained through analysis, the electrocardiogram fragment corresponding to the abnormal trends is marked, including: acquiring a trend time period corresponding to the abnormal trend; and extracting electrocardiogram fragments which are in the same time period as the trend time period from all the left atrial electrocardiogram data and the right atrial electrocardiogram data, and marking the electrocardiogram fragments.
In one embodiment, the acquiring left atrial electrocardiogram data acquired through a left atrial lead and acquiring right atrial electrocardiogram data acquired through a right atrial lead includes: acquiring positive and negative potentials of the left atrium lead in real time, and measuring and calculating to obtain a potential difference of the left atrium lead; tracing the left atrial electrocardiogram data according to the potential difference of the left atrial lead; acquiring the positive and negative electric potentials of the right atrium lead in real time, and measuring and calculating to obtain the potential difference of the right atrium lead; and obtaining the right atrium electrocardiogram data by tracing according to the potential difference of the right atrium lead.
In one embodiment, the left atrial electrocardiogram data comprises: esophageal bipolar lead electrocardiographic data; the right atrial electrocardiogram data comprises a plurality of right precordial bipolar lead electrocardiogram data; the acquiring right atrial electrocardiogram data acquired through a right atrial lead comprises: acquiring a plurality of right chest bipolar lead electrocardiogram data; extracting standard right chest bipolar lead electrocardiogram data from the plurality of right chest bipolar lead electrocardiogram data, and taking the standard right chest bipolar lead electrocardiogram data as right atrial electrocardiogram data; and taking the left right chest bipolar lead electrocardiogram data after extraction as the right atrium electrocardiogram data of the reference.
In a second aspect, an embodiment of the present invention provides an electrocardiograph recording apparatus, including:
the physiological electric signal recording device, the monitoring electrode and the data analysis device;
one end of the physiological electric signal device is provided with a plurality of detection channels, and one end of each detection channel is provided with an adapter corresponding to the detection channel;
the monitoring electrode is provided with a plurality of positive and negative electrodes which are respectively connected with the adapters corresponding to the detection channels;
the other end of the physiological electric signal device is provided with a data acquisition module, and the data acquisition module transmits acquired left atrial electrocardiogram data and right atrial electrocardiogram data to the data analysis device in real time;
the data analysis device is used for analyzing the acquired left atrial electrocardiogram data and the right atrial electrocardiogram data and determining the type of the abnormality.
In one embodiment, the electrocardiograph further comprises:
the adapter corresponding to one of the detection channels is connected with the monitoring electrode of the esophageal catheter;
and the adapters corresponding to the rest of the detection channels are respectively connected with the right chest front bipolar lead electrodes.
In a third aspect, an embodiment of the present invention provides an electrocardiogram recording apparatus, including:
the acquisition module is used for acquiring left atrial electrocardiogram data acquired through left atrial leads and acquiring right atrial electrocardiogram data acquired through right atrial leads;
the marking module is used for respectively carrying out trend analysis on the left atrial electrocardiogram data and the right atrial electrocardiogram data, and marking electrocardiogram fragments corresponding to abnormal trends when the abnormal trends are obtained through analysis;
the extraction module is used for respectively extracting a left atrium abnormal electrocardiogram fragment corresponding to the left atrium and a right atrium abnormal electrocardiogram fragment corresponding to the right atrium according to the marking result;
and the determining module is used for determining the type of the abnormality according to the abnormal electrocardiogram fragment of the left atrium and the abnormal electrocardiogram fragment of the right atrium.
In a fourth aspect, an embodiment of the present invention provides a computer-readable storage medium, in which a computer program is stored, and when the computer program is executed by a processor, the processor is caused to execute the following steps:
acquiring left atrial electrocardiogram data acquired through left atrial leads and right atrial electrocardiogram data acquired through right atrial leads;
trend analysis is respectively carried out on the electrocardiogram data of the left atrium and the electrocardiogram data of the right atrium, and when abnormal trends are obtained through analysis, electrocardiogram fragments corresponding to the abnormal trends are marked;
respectively extracting a left atrium abnormal electrocardiogram fragment corresponding to the left atrium and a right atrium abnormal electrocardiogram fragment corresponding to the right atrium according to the marking result;
and determining the abnormal type according to the abnormal electrocardiogram fragment of the left atrium and the abnormal electrocardiogram fragment of the right atrium.
The electrocardiogram recording method, the device and the storage medium acquire right atrial electrocardiogram data acquired through right atrial leads by acquiring left atrial electrocardiogram data acquired through left atrial leads, then perform trend analysis on the left atrial electrocardiogram data and the right atrial electrocardiogram data respectively, and mark electrocardiogram fragments corresponding to abnormal trends when abnormal trends are obtained through analysis; then extracting a left atrium abnormal electrocardiogram fragment corresponding to the left atrium and a right atrium abnormal electrocardiogram fragment corresponding to the right atrium according to the marking result; and finally, determining the abnormal type according to the abnormal electrocardiogram fragment of the left atrium and the abnormal electrocardiogram fragment of the right atrium. By performing trend analysis on the electrocardiogram data, marking electrocardiogram fragments corresponding to abnormal trends obtained by analysis, and determining abnormal types according to the marked abnormal electrocardiogram fragments of the left atrium and the right atrium, the right atrium and the left atrium can be accurately judged in priority.
Above-mentioned electrocardiographic recording appearance includes: the physiological electric signal recording device, the monitoring electrode and the data analysis device; one end of the physiological electric signal device is provided with a plurality of detection channels, and one end of each detection channel is provided with an adapter corresponding to the detection channel; the monitoring electrode is provided with a plurality of positive and negative electrodes which are respectively connected with the adapters corresponding to the detection channels; the other end of the physiological electric signal device is provided with a data acquisition module, and the data acquisition module transmits acquired left atrial electrocardiogram data and right atrial electrocardiogram data to the data analysis device in real time. The monitoring electrode and the physiological electric signal device are used for acquiring the left and right electrogram data in real time, and then the data acquisition module transmits the left and right electrogram data acquired in real time to the data analysis device for analysis, so that the left and right electrogram data can be acquired and analyzed in real time; and the physiological electric signal recording device, the monitoring electrode and the data analysis device are small in size, convenient to move, independent of a fixed-point power supply and a grounding support, and convenient to carry.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.
FIG. 1 is a flow chart of a method of recording an electrocardiogram according to one embodiment;
FIG. 2 is a flow diagram of determining a type of exception, under one embodiment;
FIG. 3 is a flow diagram of determining an anomaly type based on a preset waveform and a mark start time in one embodiment;
FIG. 4 is a diagram illustrating the determination of an exception type as a first exception type, under an embodiment;
FIG. 5 is a diagram illustrating the determination of an exception type as a second exception type in one embodiment;
FIG. 6 is a flow chart of labeling ECG segments corresponding to abnormal trends in one embodiment;
FIG. 7 is a flow chart of obtaining right and left atrial electrocardiogram data according to one embodiment;
FIG. 8 is a flow chart of acquiring right atrial electrocardiogram data according to one embodiment;
FIG. 9 is a schematic diagram of an electrocardiograph recorder in one embodiment;
fig. 10 is a block diagram showing the configuration of the electrocardiogram recording apparatus according to the embodiment.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.
As shown in fig. 1, an electrocardiogram recording method is proposed, which can be applied to an electrocardiogram recorder, and the present embodiment is exemplified as being applied to an electrocardiogram recorder. The electrocardiogram recording method specifically comprises the following steps:
step 102, obtaining left atrial electrocardiogram data collected through a left atrial lead, and obtaining right atrial electrocardiogram data collected through a right atrial lead.
The lead is that electrodes are placed at different parts of a human body and are connected with the anode and the cathode of an amplifier of an electrocardiogram recording machine through lead wires, and the placing positions of the electrodes at different parts of the human body and the connection mode of the electrodes and the amplifier are called as the lead; the left atrial lead refers to the placement position of an electrode at the left atrial part of a human body and the connection mode of the electrode and an amplifier, and the right atrial lead refers to the placement position of the electrode at the right atrial part of the human body and the connection mode of the electrode and the amplifier; the left atrial electrocardiogram data and the right atrial electrocardiogram data are related data of electrocardiograms acquired by a left atrial lead and a right atrial lead respectively. In one embodiment, the left atrial electrocardiogram data and the right atrial electrocardiogram data are acquired respectively according to different left and right atrial leads, the left atrial lead and the right atrial lead can be acquired according to the selection of a user, and the electrocardiogram data acquired by the different leads are different.
And 104, respectively carrying out trend analysis on the left atrial electrocardiogram data and the right atrial electrocardiogram data, and marking electrocardiogram fragments corresponding to abnormal trends when abnormal trends are obtained through analysis.
The trend analysis refers to comparing and analyzing the acquired left and right atrial electrocardiogram data with left and right atrial electrocardiogram data of the same type of indexes acquired at different periods, so as to determine the conditions of the left and right atria and the change rule of the electrocardiogram. Trend analysis may include: analyzing heart rate trend, ST-segment displacement trend and arrhythmia event frequency trend; the abnormal trend refers to a change trend different from the conventional change trend in the change trend of the electrocardiogram data; the labeling means labeling the electrocardiogram section corresponding to the abnormal trend, for example, labeling the electrocardiogram section corresponding to the abnormal trend, or labeling the electrocardiogram section corresponding to the abnormal trend with color, so that the section where the abnormal trend is observed in the electrocardiogram data can be labeled according to the color. In one embodiment, electrocardiogram segments corresponding to different abnormal trends can be marked respectively according to different abnormal attributes. Assuming that arrhythmia trend analysis is performed on the left atrial electrocardiogram data and the right atrial electrocardiogram data respectively, that is, the change rule of the heart rhythm in the left atrial electrocardiogram data and the right atrial electrocardiogram data is analyzed, when arrhythmia trend (i.e., abnormal trend) in the change rule of the heart rhythm is detected, the electrocardiogram segments corresponding to the arrhythmia trend are marked, and arrhythmia trends with different attributes can be distinguished by using different marks.
And 106, respectively extracting a left atrium abnormal electrocardiogram fragment corresponding to the left atrium and a right atrium abnormal electrocardiogram fragment corresponding to the right atrium according to the marking result.
The marking result refers to a result obtained by marking the electrocardiogram fragment corresponding to the abnormal trend. Since the abnormal trend is obtained by trend analysis of the left atrial electrocardiogram data and the right atrial electrocardiogram data, the abnormal trend can respectively correspond to the left atrial electrocardiogram fragment and the right atrial electrocardiogram fragment, so that the left atrial electrocardiogram fragment and the right atrial electrocardiogram fragment are respectively marked to obtain respectively marked results. In one embodiment, the electrocardiogram fragments marked as abnormal in the left atrial electrocardiogram data and the electrocardiogram fragments marked as the same abnormal in the right atrial electrocardiogram data can be extracted respectively according to the result of the respective marking. And by analogy, extracting corresponding left atrial electrocardiogram fragments and right atrial electrocardiogram fragments marked as the same abnormity according to the marking result.
And step 108, determining the abnormal type according to the abnormal electrocardiogram fragment of the left atrium and the abnormal electrocardiogram fragment of the right atrium.
The abnormal type refers to a category to which the abnormal trend belongs, and the abnormal type can be set to be various according to needs. In one embodiment, assuming that the abnormality types are set to three types as required, the three abnormality types can be obtained from the three different cases of the abnormal electrocardiogram fragments of the left and right atria, respectively. For example, when the condition between the abnormal electrocardiogram sections of the left atrium and the right atrium is a first condition, determining that the first condition corresponds to a first abnormal type of the three abnormal types; when the condition between the abnormal electrocardiogram fragments of the left atrium and the right atrium is a second condition, determining that the second condition corresponds to a second abnormal type in the three abnormal types; when the condition between the abnormal electrocardiogram fragments of the left atrium and the right atrium is a third condition, determining that the third condition corresponds to a third abnormal type in the three abnormal types; the type of abnormality can be determined from the left atrial abnormal electrocardiogram fragment and the right atrial abnormal electrocardiogram fragment.
By performing trend analysis on the electrocardiogram data of the left atrium and the right atrium, marking electrocardiogram fragments corresponding to abnormal trends obtained by analysis, and determining abnormal types according to the marked abnormal electrocardiogram fragments of the left atrium and the marked abnormal electrocardiogram fragments of the right atrium, the priority judgment of the left atrial wave and the right atrial wave can be accurately realized.
As shown in fig. 2, in one embodiment, the determining the type of abnormality from the left atrial abnormal electrocardiogram fragment and the right atrial abnormal electrocardiogram fragment comprises:
The preset waveform refers to waveforms corresponding to preset left and right atrial abnormal electrocardiogram fragments, for example: p-waves and A-waves; the marking result is obtained after marking the electrocardiogram fragment corresponding to the abnormal trend, and the marking result comprises the marking starting time; the marking start time is a time point at which the marking operation of the electrocardiogram section corresponding to the abnormal trend is started. In one embodiment, the preset waveform may be preset according to the user's requirement, for example, when the user needs to observe the P-wave of the abnormal electrocardiogram segment of the left and right atria, the P-wave may be set as the preset waveform.
And 204, determining the type of the abnormity according to the preset waveform and the mark starting time.
The abnormal type refers to a category to which the abnormal trend belongs, and the abnormal type can be set to be various according to the requirements of users. In one embodiment, the corresponding anomaly type may be determined from a relationship between a preset waveform and a marker start time. For example, it is assumed that the abnormality types are set to three types, which correspond to three relationships between the preset waveform and the marker start time, respectively. When the relation between the preset waveform and the mark starting time is a first relation of the three relations, determining that the first relation corresponds to a first abnormal type of the three abnormal types; when the relationship between the preset waveform and the mark starting time is a second relationship of the three relationships, determining that the second relationship corresponds to a second abnormal type of the three abnormal types; and when the relationship between the preset waveform and the mark start time is a third relationship of the three relationships, determining that the third relationship corresponds to a third abnormality type of the three abnormality types. According to the relation between the preset waveform and the mark starting time, the abnormal type can be determined according to different relations between the preset waveform and the mark starting time, so that the determined abnormal type is more accurate, and the accurate judgment on the left atrial wave and the right atrial wave in priority is realized.
As shown in fig. 3, in an embodiment, the determining the type of the abnormality according to the preset waveform and the mark start time includes:
The occurrence time refers to the time point when the preset waveform appears in each left and right atrial abnormal electrocardiogram segment, and the occurrence sequence refers to the sequence of the preset waveform appearing in each left and right abnormal electrocardiogram segment. After marking the start time, acquiring the occurrence time of the preset waveform in each of the abnormal electrocardiogram fragments of the left atrium and the right atrium, because the preset waveform may occur in each of the abnormal electrocardiogram fragments of the left atrium and the right atrium; in each of the left and right atrial abnormal electrocardiogram fragments, the occurrence times of the preset waveforms may be the same or different, so that the obtained occurrence times need to be sorted in time sequence, and the occurrence sequence of the preset waveforms in all the abnormal electrocardiogram fragments is obtained according to the sorting, so that whether the preset waveforms are firstly present in the left atrial abnormal electrocardiogram fragment or the right atrial abnormal electrocardiogram fragment can be judged according to the occurrence sequence.
The first abnormal type refers to a category to which a preset first abnormal trend belongs, and the first abnormal type corresponds to a condition of a preset waveform in the abnormal electrocardiogram section of the left atrium and the right atrium, that is, the first abnormal type corresponds to a condition that the preset waveform appears in the abnormal electrocardiogram section of the left atrium first. As shown in fig. 4, in one embodiment, when the preset waveform appears in the abnormal left atrial electrocardiogram fragment first, it may be determined that an abnormal trend appears in the abnormal left atrial electrocardiogram fragment first, and the category to which the abnormal trend belongs may be determined as the first abnormal type.
The second abnormal type is a category to which a preset second abnormal trend belongs, and the second abnormal type corresponds to a condition of a preset waveform in the abnormal electrocardiogram fragment of the left atrium and the right atrium, that is, the second abnormal type corresponds to a condition that the preset waveform appears in the abnormal electrocardiogram fragment of the right atrium first. As shown in fig. 5, in one embodiment, when the preset waveform first appears in the right atrial abnormal electrocardiogram fragment, it may be determined that an abnormal trend first appears in the right atrial abnormal electrocardiogram fragment, and the category to which the abnormal trend belongs may be determined as the second abnormal type.
And 310, when the preset waveforms simultaneously appear, determining that the abnormal left atrium electrocardiogram section and the abnormal right atrium electrocardiogram section are of a third abnormal type.
The third abnormal type is a category to which a preset third abnormal trend belongs, and the third abnormal type corresponds to a condition of a preset waveform in the abnormal left atrium and the abnormal right atrium electrocardiogram sections, that is, the third abnormal type corresponds to a condition that the preset waveform appears in the abnormal left atrium electrocardiogram section and the abnormal right atrium section at the same time. In one embodiment, when the preset waveform is simultaneously present in the left atrial abnormal electrocardiogram section and the right atrial abnormal electrocardiogram section, it may be determined that the abnormal trend is simultaneously present in the left and right atrial abnormal electrocardiogram sections, and the category to which the abnormal trend belongs may be determined as the third abnormal type. The abnormal electrocardiogram fragment with the first occurrence of the preset waveform is obtained by judging the occurrence sequence of the preset waveform in all the abnormal electrocardiogram fragments, so that the abnormal trend of the abnormal electrocardiogram fragment with the first occurrence of the preset waveform can be judged, the abnormal trend of the abnormal electrocardiogram fragment with the right atrium can be judged, or the abnormal trend of the abnormal electrocardiogram fragments with the left atrium and the right atrium can be judged simultaneously, and the category of the abnormal trend can be further determined, namely, the abnormal type can be determined and obtained for judging the priority of the left atrial wave and the right atrial wave.
As shown in FIG. 6, in one embodiment, the trend analysis includes: heart rate trend analysis, ST-segment shift trend analysis and arrhythmia event frequency trend analysis. The analysis of the heart rate trend refers to the analysis of the change of the heart rate regularly, the analysis of the ST-segment shift trend refers to the analysis of the change of the ST-segment shift regularly, and the analysis of the trend of the arrhythmia time attack frequency refers to the analysis of the change of the arrhythmia time attack frequency regularly. By analyzing the electrocardiogram data of the left atrium and the right atrium, the change rule of the heart rate, the change rule of ST-segment displacement and the change rule of the time attack frequency of arrhythmia can be obtained. The trend analysis is performed on the left atrial electrocardiogram data and the right atrial electrocardiogram data respectively, and when abnormal trends are obtained through analysis, the electrocardiogram fragment corresponding to the abnormal trends is marked, including:
The trend time period is a time difference between a start time and an end time when an abnormal trend appears in the electrocardiogram data of the left atrium and the right atrium. Since the abnormal trend is different from the conventional trend in the trend of the electrocardiogram data of the left atrium and the right atrium, the analyzed abnormal trend corresponds to the abnormal trend starting time and the abnormal trend ending time, and the time difference between the abnormal trend starting time and the abnormal trend ending time can be used as the trend time period of the abnormal trend for marking the electrocardiogram segment corresponding to the abnormal trend subsequently.
And step 604, extracting electrocardiogram fragments which are in the same time period as the trend time period from all the left atrial electrocardiogram data and the right atrial electrocardiogram data, and marking the electrocardiogram fragments.
The same time period as the trend time period refers to a time period equal to both the start time and the end time of the trend time period. Since the left atrial electrocardiogram data and the right atrial electrocardiogram data are acquired simultaneously, and the electrocardiogram fragment corresponding to the abnormal trend can be the left atrial electrocardiogram fragment and the right atrial electrocardiogram fragment, all the electrocardiogram fragments need to be marked simultaneously. In one embodiment, all the extracted electrocardiogram segments can be marked by respectively acquiring electrocardiogram segments which are the same as the starting time and the ending time of the trend time period in all the electrocardiogram data, namely extracting the electrocardiogram segments which are the same time period as the trend time period, so that the marking of all the electrocardiogram segments can be realized at the same time. The trend time period is utilized to extract the electrocardiogram fragments of all electrocardiogram data, so that the electrocardiogram fragments corresponding to abnormal trends can be simultaneously marked, and the abnormal electrocardiogram fragments in the left atrium and the abnormal electrocardiogram fragments in the right atrium can be accurately extracted.
As shown in fig. 7, in one embodiment, the acquiring left atrial electrocardiogram data acquired through a left atrial lead and acquiring right atrial electrocardiogram data acquired through a right atrial lead includes:
and 702, acquiring positive and negative potentials of the left atrial lead in real time, and measuring and calculating to obtain the potential difference of the left atrial lead.
The positive electrode and the negative electrode of the left atrium lead are electrodes arranged at the left atrium part of the human body and comprise a positive electrode and a negative electrode; the potential difference refers to the difference between the positive electrode potential and the negative electrode potential. In one embodiment, the electrodes disposed in the left atrial region of the body may be electrodes of an esophageal catheter. Wherein, the positive pole can be the top electrode of the esophageal catheter, and the negative pole can be the side ring electrode of the esophageal catheter. The potential of the top electrode of the esophageal catheter and the potential of the side ring electrode of the esophageal catheter can be acquired in real time; and measuring and calculating the potential difference of the left atrial lead, namely measuring and calculating the potential difference between the potential of the top electrode of the esophageal catheter and the potential of the side ring electrode of the esophageal catheter, so as to obtain the potential difference of the left atrial lead.
And step 704, tracing and obtaining the left atrium electrocardiogram data according to the potential difference of the left atrium leads.
Wherein tracing refers to tracing a recording. The potential difference between the positive electrode potential and the negative electrode potential of the left atrial lead can reflect the potential relation between the positive electrode potential and the negative electrode potential of the left atrial lead, for example, when the potential difference is greater than zero, the positive electrode potential can be obtained to be higher than the negative electrode potential; when the potential difference is less than zero, the potential of the positive electrode is lower than that of the negative electrode; when the potential difference is equal to zero, the positive electrode potential is equal to the negative electrode potential; therefore, the left atrial electrocardiogram data can be drawn and recorded according to the potential difference of the left atrial lead. In one embodiment, the judgment can be made according to the calculated potential difference, that is, when the potential difference is greater than zero, the positive electrode potential is higher than the negative electrode potential, and an upward waveform can be traced; when the potential difference is less than zero, the potential of the negative electrode potential is higher than that of the positive electrode potential, and a downward waveform is traced. Therefore, the electrocardiogram data of the left atrium can be obtained by tracing according to the potential difference acquired in real time.
And step 706, acquiring the positive and negative electric potentials of the right atrial lead in real time, and measuring and calculating to obtain the potential difference of the right atrial lead.
Wherein, the positive and negative electrodes of the right atrium lead refer to electrodes arranged at the right atrium part of the human body, and comprise a positive electrode and a negative electrode; the potential difference refers to the difference between the positive electrode potential and the negative electrode potential. In one embodiment, the right atrial lead may be a right anterior chest bipolar lead. Wherein, the positive pole can be positioned between 4 ribs or xiphoid process on the right edge of the sternum, and the negative pole can be positioned between 2 ribs on the right edge of the sternum or the sternum. The positive electrode potential and the negative electrode potential in front of the right chest can be obtained in real time; and measuring the potential difference of the right atrial lead, namely measuring the potential difference between the electrode potential between 4 ribs on the right edge of the sternum and the electrode potential of the sternum peduncle, so as to obtain the potential difference of the right atrial lead.
And 708, obtaining right atrial electrocardiogram data by tracing according to the potential difference of the right atrial lead.
Wherein tracing refers to tracing a recording. The potential difference between the positive electrode potential and the negative electrode potential of the right atrial lead can reflect the potential relation between the positive electrode and the negative electrode of the right atrial lead, for example, when the potential difference is greater than zero, the positive electrode potential can be obtained to be higher than the negative electrode potential; when the potential difference is less than zero, the potential of the positive electrode is lower than that of the negative electrode; when the potential difference is equal to zero, the positive electrode potential is equal to the negative electrode potential; therefore, right atrial electrocardiogram data can be obtained by drawing and recording according to the potential difference of the right atrial lead. In one embodiment, the judgment can be made according to the calculated potential difference, that is, when the potential difference is greater than zero, the positive electrode potential is higher than the negative electrode potential, and an upward waveform can be traced; when the potential difference is less than zero, the potential of the negative electrode potential is higher than that of the positive electrode potential, and a downward waveform is traced. Therefore, right atrial electrocardiogram data can be obtained by tracing according to the potential difference acquired in real time.
As shown in fig. 8, in one embodiment, the left atrial electrocardiogram data includes: esophageal bipolar lead electrocardiographic data; the right atrial electrocardiogram data comprises a plurality of right chest bipolar lead electrocardiogram data. The esophagus bipolar lead electrocardiogram data refers to electrocardiogram data obtained by esophagus lead correspondence. Because the motor part of the esophagus leads is positioned in the esophagus behind the left atrium, the esophagus leads have very obvious expression advantages for the depolarization of the atrium, and particularly have important application value in the aspect of differential diagnosis of complicated and difficult electrocardiograms (such as separating and searching atrioventricular of wide QRS tachycardia), so that the esophagus bipolar lead electrocardiogram data can be used as the electrocardiogram data of the left atrium; the right chest bipolar lead electrocardiogram data is electrocardiogram data which is obtained by corresponding leads in the front of the right chest of a human body. By providing a plurality of right chest bipolar leads, when one of the right chest bipolar lead electrocardiogram data is not satisfactory, the rest right chest bipolar lead electrocardiogram data can be used as auxiliary reference lead electrocardiogram data.
The acquiring right atrial electrocardiogram data acquired through a right atrial lead comprises:
Since the right chest bipolar lead electrocardiogram data is obtained by connecting the electrodes on the right chest surface of the human body in a manner corresponding to the amplifier, a detection gap may exist in the right atrium electrocardiogram data obtained by corresponding to one right chest bipolar lead, and in one embodiment, the detection gap may be avoided by acquiring a plurality of right chest bipolar lead electrocardiogram data. For example, a first right anterior chest bipolar lead and a second right anterior chest bipolar lead are provided, the positive pole of the first right anterior chest bipolar lead may be located between 4 ribs of the right edge of the sternum, and the negative pole may be located at the manubrium; the positive pole of the second right anterior chest bipolar lead can be located at the xiphoid process, and the negative pole can be located between 2 ribs on the right edge of the sternum; thereby obtaining first right anterior chest bipolar lead electrocardiogram data and second right anterior chest bipolar lead electrocardiogram data.
The standard right chest bipolar lead electrocardiogram data is the right chest bipolar lead electrocardiogram data which best meets the requirement in the plurality of right chest bipolar lead electrocardiogram data. In one embodiment, since the plurality of right precordial bipolar lead electrocardiographic data do not necessarily all meet the requirement, one of the right precordial bipolar lead electrocardiographic data that best meets the requirement can be extracted as the right atrial electrocardiographic data for subsequent analysis and labeling of the right atrial electrocardiographic data.
And step 806, taking the left right chest bipolar lead electrocardiogram data after extraction as the right atrium electrocardiogram data of reference.
The left right chest bipolar lead electrocardiogram data after extraction refers to the left right chest bipolar lead electrocardiogram data after the standard right chest bipolar lead electrocardiogram data is extracted from the plurality of right chest bipolar lead electrocardiogram data. Since the standard right chest bipolar lead electrocardiogram data is the right chest bipolar lead electrocardiogram data which best meets the requirement, the left right chest bipolar lead electrocardiogram data after extraction can be used as an auxiliary reference right atrium electrocardiogram data for a reference group for carrying out analysis and marking operation on the right atrium electrocardiogram data. By acquiring multiple groups of right chest front bipolar lead electrocardiogram data, the detection vacancy of the right atrium can be avoided, and the right atrium electrocardiogram data can be accurately acquired.
As shown in fig. 9, an embodiment of the present invention provides an electrocardiograph recorder, including: a physiological electrical signal recording device 902, a monitoring electrode 904, a data analysis device 906;
one end of the physiological electric signal device 902 is provided with a plurality of detection channels 9021, and one end of each detection channel 9021 is provided with an adapter 9022 corresponding to the detection channel. The physiological electrical signal device 902 is used to collect physiological electrical signals of the left atrium and the right atrium, the detection channel 9021 is used to obtain physiological electrical signal data, and the adapter 9022 is used to connect the monitoring electrode 904.
The monitoring electrode 904 is provided with a plurality of positive and negative electrodes, and the positive and negative electrodes are respectively connected with the adapters 9022 corresponding to the detection channels 9021. Wherein, can have two adapters on a detection channel, two adapters are connected with anodal and negative pole respectively.
The other end of the physiological electric signal device 902 is provided with a data acquisition module 9023; the data acquisition module 9023 transmits the acquired left atrial electrocardiogram data and right atrial electrocardiogram data to the data analysis device 906 in real time. The data acquisition module 9023 is configured to acquire electrocardiogram data of the left atrium and the right atrium. In one embodiment, the data acquisition module 9023 may transmit the acquired electrocardiographic data to the data analysis device 906 in real time via bluetooth communication.
The data analysis device 906 is configured to analyze the acquired left atrial electrocardiogram data and the right atrial electrocardiogram data and determine the type of abnormality.
The data analysis device 906 is configured to perform real-time analysis on the real-time acquired electrocardiogram data of the left atrium and the right atrium. The data analysis device 906 may be a display terminal such as a mobile phone or a tablet computer, and the display terminal may be equipped with corresponding signal data recovery and analysis software. In addition to the event segment analysis, the signal data recovery and analysis software can also have a relatively complete trend analysis function, and can realize trend analysis of the electrocardiogram data of the left atrium and the right atrium, such as heart rate trend analysis, ST segment shift trend analysis, arrhythmia event frequency trend analysis and the like. The data analysis device 906 may also be configured to determine the abnormality type, for example, obtaining an abnormal trend according to trend analysis, marking electrocardiogram segments corresponding to the abnormal trend, and determining the abnormality type according to the marked left and right abnormal electrocardiogram segments.
In one embodiment, the electrocardiograph further comprises:
the adapter corresponding to one of the detection channels 9021 is connected to the monitoring electrode of the esophageal catheter. Wherein, the monitoring electrode of the esophageal catheter refers to an electrode of the esophageal catheter and comprises a positive electrode and a negative electrode. In one embodiment, the positive electrode of the esophageal lead electrode can be connected with the esophageal top electrode, the negative electrode can be connected with the side ring electrode, and the monitoring electrode of the esophageal catheter can be used as a left atrium monitoring electrode when acquiring left atrium lead electrocardiogram data.
The adapters corresponding to the remaining detection channels in the plurality of detection channels 9021 are respectively connected with the plurality of right chest anterior bipolar lead electrodes. The right chest front bipolar lead electrode is an electrode on the surface of the right chest of a human body and comprises a positive electrode and a negative electrode. In one embodiment, the positive electrode of the electrode on the surface of the right chest of the human body can be positioned between 4 ribs or xiphoid process on the right margin of the sternum, the negative electrode can be positioned between 2 ribs on the right margin of the sternum or the sternum, and the electrode on the surface of the right chest of the human body can be used as a right atrium monitoring electrode when right atrium lead electrocardiogram data is acquired.
As shown in fig. 10, an embodiment of the present invention provides an electrocardiogram recording apparatus, including:
an obtaining module 1002, configured to obtain left atrial electrocardiogram data acquired through a left atrial lead, and obtain right atrial electrocardiogram data acquired through a right atrial lead;
a marking module 1004, configured to perform trend analysis on the left atrial electrocardiogram data and the right atrial electrocardiogram data, respectively, and mark an electrocardiogram fragment corresponding to an abnormal trend when the abnormal trend is obtained through analysis;
an extraction module 1006, configured to extract a left atrial abnormal electrocardiogram fragment corresponding to the left atrium and a right atrial abnormal electrocardiogram fragment corresponding to the right atrium according to the labeling result;
a determining module 1008 determines the type of abnormality from the left atrial abnormal electrocardiogram fragment and the right atrial abnormal electrocardiogram fragment.
In one embodiment, the determining the type of abnormality from the left atrial abnormal electrocardiogram fragment and the right atrial abnormal electrocardiogram fragment comprises: the obtaining module 1002 is further configured to obtain a preset waveform, and obtain a marking start time of the abnormal left atrium electrocardiogram fragment and the abnormal right atrium electrocardiogram fragment in the marking result; the determining module 1008 is further configured to determine an anomaly type according to the preset waveform and the mark start time.
In one embodiment, the determining the type of abnormality according to the preset waveform and the mark start time includes: the obtaining module 1002 is further configured to obtain, after the marking start time, occurrence times of the preset waveforms appearing in each of the left atrial abnormal electrocardiogram fragments and the right atrial abnormal electrocardiogram fragments, sort the obtained occurrence times, and the determining module 1008 is further configured to determine an occurrence order of the preset waveforms in all abnormal electrocardiogram fragments according to the sorting; the determining module 1008 is further configured to determine the abnormal left atrial electrocardiogram fragment as a first abnormal type when the preset waveform appears in the abnormal left atrial electrocardiogram fragment first; the determining module 1008 is further configured to determine that the right atrial abnormal electrocardiogram fragment is of a second abnormal type when the preset waveform appears in the right atrial abnormal electrocardiogram fragment first; the determining module 1008 is further configured to determine that the abnormal left atrial electrocardiogram fragment and the abnormal right atrial electrocardiogram fragment are of a third abnormal type when the preset waveforms occur simultaneously.
In one embodiment, the trend analysis includes: analyzing heart rate trend, ST-segment displacement trend and arrhythmia event frequency trend; the trend analysis is performed on the left atrial electrocardiogram data and the right atrial electrocardiogram data respectively, and when abnormal trends are obtained through analysis, the electrocardiogram fragment corresponding to the abnormal trends is marked, including: the obtaining module 1002 is further configured to obtain a trend time period corresponding to the abnormal trend; the marking module 1004 is further configured to extract all electrocardiogram fragments in the left atrial electrocardiogram data and the right atrial electrocardiogram data, which are in the same time period as the trend time period, and mark the electrocardiogram fragments.
In one embodiment, the acquiring left atrial electrocardiogram data acquired through a left atrial lead and acquiring right atrial electrocardiogram data acquired through a right atrial lead includes: the obtaining module 1002 is further configured to obtain positive and negative potentials of the left atrial lead in real time, and measure and calculate to obtain a potential difference of the left atrial lead; the extraction module 1006 is further configured to trace the left atrial electrocardiogram data according to the potential difference of the left atrial lead; the obtaining module 1002 is further configured to obtain positive and negative potentials of the right atrial lead in real time, and measure and calculate to obtain a potential difference of the right atrial lead; the extraction module 1006 is further configured to trace right atrial electrocardiogram data according to the potential difference of the right atrial lead.
In one embodiment, the left atrial electrocardiogram data comprises: esophageal bipolar lead electrocardiographic data; the right atrial electrocardiogram data comprises a plurality of right precordial bipolar lead electrocardiogram data; the acquiring right atrial electrocardiogram data acquired through a right atrial lead comprises: the obtaining module 1002 is further configured to obtain a plurality of right anterior chest bipolar lead electrocardiographic data; the extracting module 1006 is further configured to extract standard right anterior chest bipolar lead electrocardiogram data from the plurality of right anterior chest bipolar lead electrocardiogram data, and use the standard right anterior chest bipolar lead electrocardiogram data as right atrial electrocardiogram data; the obtaining module 1002 is further configured to use the left right anterior chest bipolar lead electrocardiogram data after extraction as right atrial electrocardiogram data for reference.
A computer-readable storage medium storing a computer program which, when executed by a processor, causes the processor to perform the steps of: acquiring left atrial electrocardiogram data acquired through left atrial leads and right atrial electrocardiogram data acquired through right atrial leads; trend analysis is respectively carried out on the electrocardiogram data of the left atrium and the electrocardiogram data of the right atrium, and when abnormal trends are obtained through analysis, electrocardiogram fragments corresponding to the abnormal trends are marked; respectively extracting a left atrium abnormal electrocardiogram fragment corresponding to the left atrium and a right atrium abnormal electrocardiogram fragment corresponding to the right atrium according to the marking result; and determining the abnormal type according to the abnormal electrocardiogram fragment of the left atrium and the abnormal electrocardiogram fragment of the right atrium.
In one embodiment, the determining the type of abnormality from the left atrial abnormal electrocardiogram fragment and the right atrial abnormal electrocardiogram fragment comprises:
acquiring a preset wave pattern, and acquiring the marking start time of the abnormal left atrium electrocardiogram fragment and the abnormal right atrium electrocardiogram fragment in the marking result;
and determining the type of the abnormity according to the preset wave pattern and the mark starting time.
In one embodiment, said determining the type of anomaly from said preset waveform and said marker start time comprises: after the marking start time, acquiring the occurrence time of the preset wave pattern of each of the left atrial abnormal electrocardiogram fragments and the right atrial abnormal electrocardiogram fragments, sequencing the obtained occurrence time, and determining the occurrence sequence of the wave patterns in all abnormal electrocardiogram fragments according to the sequencing; when the abnormal left atrium electrocardiogram fragment appears in the preset wave pattern first, determining the abnormal left atrium electrocardiogram fragment as a first abnormal type; when the preset waveform appears in the right atrial abnormal electrocardiogram fragment first, determining the right atrial abnormal electrocardiogram fragment as a second abnormal type; and when the preset waveforms simultaneously appear, determining the abnormal left atrium and the abnormal right atrium as a third abnormal type.
In one embodiment, the trend analysis includes: analyzing heart rate trend, ST-segment displacement trend and arrhythmia event frequency trend; the trend analysis is performed on the left atrial electrocardiogram data and the right atrial electrocardiogram data respectively, and when abnormal trends are obtained through analysis, the electrocardiogram fragment corresponding to the abnormal trends is marked, including: acquiring a trend time period corresponding to the abnormal trend; and extracting electrocardiogram fragments which are in the same time period as the trend time period from all the left atrial electrocardiogram data and the right atrial electrocardiogram data, and marking the electrocardiogram fragments.
In one embodiment, the acquiring left atrial electrocardiogram data acquired through a left atrial lead and acquiring right atrial electrocardiogram data acquired through a right atrial lead includes: acquiring positive and negative potentials of the left atrium lead in real time, and measuring and calculating to obtain a potential difference of the left atrium lead; tracing the left atrial electrocardiogram data according to the potential difference of the left atrial lead; acquiring the positive and negative electric potentials of the right atrium lead in real time, and measuring and calculating to obtain the potential difference of the right atrium lead; and obtaining the right atrium electrocardiogram data by tracing according to the potential difference of the right atrium lead.
In one embodiment, the left atrial electrocardiogram data comprises: esophageal bipolar lead electrocardiographic data; the right atrial electrocardiogram data comprises a plurality of right precordial bipolar lead electrocardiogram data; the acquiring right atrial electrocardiogram data acquired through a right atrial lead comprises: acquiring a plurality of right chest bipolar lead electrocardiogram data; extracting standard right chest bipolar lead electrocardiogram data from the plurality of right chest bipolar lead electrocardiogram data, and taking the standard right chest bipolar lead electrocardiogram data as right atrial electrocardiogram data; and taking the left right chest bipolar lead electrocardiogram data after extraction as the right atrium electrocardiogram data of the reference.
It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, which can be stored in a non-volatile computer-readable storage medium, and can include the processes of the embodiments of the methods described above when the program is executed. Any reference to memory, storage, database, or other medium used in the embodiments provided herein may include non-volatile and/or volatile memory, among others. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDRSDRAM), Enhanced SDRAM (ESDRAM), Synchronous Link DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).
The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.
The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present application. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.
Claims (10)
1. A method of electrocardiographic recording, the method comprising:
acquiring left atrial electrocardiogram data acquired through left atrial leads and right atrial electrocardiogram data acquired through right atrial leads;
trend analysis is respectively carried out on the electrocardiogram data of the left atrium and the electrocardiogram data of the right atrium, and when abnormal trends are obtained through analysis, electrocardiogram fragments corresponding to the abnormal trends are marked;
respectively extracting a left atrium abnormal electrocardiogram fragment corresponding to the left atrium and a right atrium abnormal electrocardiogram fragment corresponding to the right atrium according to the marking result;
and determining the abnormal type according to the abnormal electrocardiogram fragment of the left atrium and the abnormal electrocardiogram fragment of the right atrium.
2. The method of claim 1, wherein said determining an abnormality type from said left atrial abnormal electrocardiogram fragment and said right atrial abnormal electrocardiogram fragment comprises:
acquiring a preset waveform, and acquiring the marking start time of the abnormal left atrium electrocardiogram fragment and the abnormal right atrium electrocardiogram fragment in the marking result;
and determining the type of the abnormity according to the preset waveform and the mark starting time.
3. The method of claim 2, wherein said determining an anomaly type from said preset waveform and said marker start time comprises:
after the marking start time, acquiring the occurrence time of the preset waveform of each abnormal electrocardiogram fragment of the left atrium and the abnormal electrocardiogram fragment of the right atrium, sequencing the obtained occurrence time, and determining the occurrence sequence of the preset waveform in all the abnormal electrocardiogram fragments according to the sequencing;
when the preset waveform appears in the abnormal electrocardiogram fragment of the left atrium first, determining the abnormal electrocardiogram fragment of the left atrium to be a first abnormal type;
when the preset waveform appears in the abnormal right atrium electrocardiogram fragment first, determining the abnormal right atrium electrocardiogram fragment to be of a second abnormal type;
and when the preset waveforms simultaneously appear, determining the abnormal left atrium electrocardiogram section and the abnormal right atrium electrocardiogram section to be a third abnormal type.
4. The method of claim 1, wherein the trend analysis comprises: analyzing heart rate trend, ST-segment displacement trend and arrhythmia event frequency trend;
the trend analysis is performed on the left atrial electrocardiogram data and the right atrial electrocardiogram data respectively, and when abnormal trends are obtained through analysis, the electrocardiogram fragment corresponding to the abnormal trends is marked, including:
acquiring a trend time period corresponding to the abnormal trend;
and extracting electrocardiogram fragments which are in the same time period as the trend time period from all the left atrial electrocardiogram data and the right atrial electrocardiogram data, and marking the electrocardiogram fragments.
5. The method of claim 1, wherein acquiring left atrial electrocardiogram data acquired via a left atrial lead and acquiring right atrial electrocardiogram data acquired via a right atrial lead comprises:
acquiring positive and negative potentials of the left atrium lead in real time, and measuring and calculating to obtain a potential difference of the left atrium lead;
tracing the left atrial electrocardiogram data according to the potential difference of the left atrial lead;
acquiring the positive and negative electric potentials of the right atrium lead in real time, and measuring and calculating to obtain the potential difference of the right atrium lead;
and obtaining the right atrium electrocardiogram data by tracing according to the potential difference of the right atrium lead.
6. The method of claim 5, wherein the left atrial electrocardiogram data comprises: esophageal bipolar lead electrocardiographic data; the right atrial electrocardiogram data comprises a plurality of right precordial bipolar lead electrocardiogram data;
the acquiring right atrial electrocardiogram data acquired through a right atrial lead comprises:
acquiring a plurality of right chest bipolar lead electrocardiogram data;
extracting standard right chest bipolar lead electrocardiogram data from the plurality of right chest bipolar lead electrocardiogram data, and taking the standard right chest bipolar lead electrocardiogram data as right atrial electrocardiogram data;
and taking the left right chest bipolar lead electrocardiogram data after extraction as the right atrium electrocardiogram data of the reference.
7. An electrocardiograph recording instrument, comprising: the physiological electric signal recording device, the monitoring electrode and the data analysis device;
one end of the physiological electric signal device is provided with a plurality of detection channels, and one end of each detection channel is provided with an adapter corresponding to the detection channel;
the monitoring electrode is provided with a plurality of positive and negative electrodes which are respectively connected with the adapters corresponding to the detection channels;
the other end of the physiological electric signal device is provided with a data acquisition module, and the data acquisition module transmits acquired left atrial electrocardiogram data and right atrial electrocardiogram data to the data analysis device in real time;
the data analysis device is used for analyzing the acquired left atrial electrocardiogram data and the right atrial electrocardiogram data and determining the type of the abnormality.
8. The recorder of claim 7, wherein the electrocardiograph recorder further comprises:
the adapter corresponding to one of the detection channels is connected with the monitoring electrode of the esophageal catheter;
and the adapters corresponding to the rest of the detection channels are respectively connected with the right chest front bipolar lead electrodes.
9. An electrocardiogram recording apparatus, characterized in that it comprises:
the acquisition module is used for acquiring left atrial electrocardiogram data acquired through left atrial leads and acquiring right atrial electrocardiogram data acquired through right atrial leads;
the marking module is used for respectively carrying out trend analysis on the left atrial electrocardiogram data and the right atrial electrocardiogram data, and marking electrocardiogram fragments corresponding to abnormal trends when the abnormal trends are obtained through analysis;
the extraction module is used for respectively extracting a left atrium abnormal electrocardiogram fragment corresponding to the left atrium and a right atrium abnormal electrocardiogram fragment corresponding to the right atrium according to the marking result;
and the determining module is used for determining the type of the abnormality according to the abnormal electrocardiogram fragment of the left atrium and the abnormal electrocardiogram fragment of the right atrium.
10. A computer-readable storage medium, storing a computer program which, when executed by a processor, causes the processor to carry out the steps of the method according to any one of claims 1 to 6.
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