JP4108449B2 - Method for predicting therapeutic effect of oxygen therapy, method for supporting the implementation of oxygen therapy - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for predicting the therapeutic effect of oxygen therapy and a method for supporting the implementation of oxygen therapy, and in particular, an oxygen concentrator is installed in a patient's home, and the home patient inhales the oxygen-enriched gas supplied by the oxygen concentrator. However, the present invention relates to a configuration suitable for enabling a health care professional to predict the effect when home oxygen therapy for stabilizing the condition is performed on a patient with chronic heart failure.
[0002]
[Prior art]
Conventionally, oxygen therapy to be supplied from an oxygen cylinder to a patient with respiratory disease has been performed, and recently, a respiratory gas supply device (hereinafter referred to as an oxygen-enriched gas) for separating and concentrating oxygen in the air to obtain an oxygen-enriched gas. Oxygen concentrators) have been developed, and oxygen therapy using them has become increasingly popular.
[0003]
Such oxygen therapy may be performed while the patient is admitted to a medical institution, but the patient's respiratory illness presents chronic symptoms, and this oxygen therapy is performed over a long period of time to stabilize and stabilize the symptoms. When it is necessary to install the oxygen concentrator in the patient's home, the oxygen-enriched gas supplied by the oxygen concentrator is guided to the vicinity of the patient's nasal cavity using a tube member called a cannula. There is also a treatment method in which a patient performs suction. This type of home oxygen therapy is also called HOT (Home Oxygen Therapy).
[0004]
The above-mentioned home oxygen therapy has been prescribed mainly for chronic obstructive pulmonary disease (COPD) and pulmonary tuberculosis sequelae since insurance was applied in 1985. The outline of the number of patients is 10 in Japan. 60 to 65 people per million, or about 80,000 people (as of 2000). In addition, the former Ministry of Health and Welfare Respiratory Failure Team has reported that this home oxygen therapy improves the patient's prognosis. The reason why home oxygen therapy is effective in this way is presumed to be due to improvement in pulmonary circulation dynamics accompanying improvement in hypoxemia.
[0005]
The process from introduction of the above-mentioned home oxygen therapy to the patient and continuing treatment will be described in order.
[0006]
First, a patient with respiratory illness visits a medical institution and sees a doctor. As a result of the examination, when this doctor determines that this patient needs the above-mentioned home oxygen therapy, the doctor performs introduction for receiving home oxygen therapy and initial medical guidance for this patient. The above guidance may be given by staying at this medical institution for a predetermined number of days, or by receiving referral to another medical institution, such as a regional core basic hospital, and being admitted to this basic hospital. There is also.
[0007]
As a result of the above introduction and initial medical guidance, if the progress is good, the doctor in charge issues an instruction to the patient with a prescription to perform home oxygen therapy. Based on the issued instructions, the oxygen concentrator supplier who has signed a contract with this medical institution will carry the prescription-based oxygen concentrator into this patient's home, and this patient will be based on prescription-based home oxygen therapy. Install an oxygen concentrator and set various conditions so that it can be properly received.
[0008]
When the preparation is completed by the above procedure, the patient is at home and continuously receives home oxygen therapy for aspirating the oxygen-enriched gas supplied by the installed oxygen concentrator. In addition, in order for this home oxygen therapy to receive the application of health insurance, it is necessary to always receive a doctor's examination at an outpatient or home visit once a month.
[0009]
By the way, in addition to the above-mentioned chronic obstructive pulmonary disease (COPD), pulmonary tuberculosis sequelae, etc., chronic heart failure (hereinafter also referred to as CHF: Chronic Heart Failure) has been proposed as a disease to which home oxygen therapy described above should be applied. ing. The reason for applying home oxygen therapy for this CHF is mainly to improve CHF-Stokes respiration, which often appears in CHF, and to reduce the symptoms of CHF patients.
[0010]
Hereinafter, the effect of the treatment method of giving oxygen therapy to a patient with chronic heart failure (CHF) will be described based on known materials.
[0011]
[Effects of oxygen therapy for chronic heart failure]
[1. Introduction]
Chronic heart failure (CHF) is defined as a syndrome that results in peripheral circulatory disturbance, exercise tolerance, quality of life, and worsening of life prognosis due to chronic left ventricular dysfunction. The goal of treatment for chronic heart failure is to suppress the progression of cardiac dysfunction (prevent acute exacerbations) and improve subjective symptoms, exercise tolerance, quality of life, and life prognosis.
[0012]
Treatment for CHF mainly consists of daily life management such as pharmacotherapy mainly with diuretics, ACE inhibitors, β-Blocker, dietary guidance and patient education.
Oxygen therapy is said to increase arterial oxygen saturation and reduce pulmonary vascular resistance. Oxygen therapy is performed at the time of hospitalization due to acute exacerbation of chronic heart failure.
[0013]
[2. CHF night-time respiratory status and prognosis]
In recent years, CHF is said to be associated with Cheyne-Stokes breathing (CSR, symptom of repeated increase and decrease of respiratory airflow followed by central apnea or hypopnea) in 40% of CHF. As a result of a follow-up survey of patients with CSR and those without CSR, 1 out of 7 cases died and 5 out of 9 cases with CSR Two deaths and heart transplantation (heart death). As a result, it was shown that patients with a CSR merger had a poor prognosis compared to the case without a CSR merger (Non-patent Document 1).
[0014]
[3. Effect of oxygen therapy on CHF]
CSR is often observed in CHF, with nighttime hypoxia and sleep disturbance due to arousal. Nocturnal hypoxia and arousal cause increased pulmonary artery pressure and sympathetic nerve activity, reducing exercise tolerance.
[0015]
Oxygen therapy is effective in improving CSR and is expected to improve exercise tolerance in CHF patients with CSR. Oxygen therapy and air inhalation were performed for 1 week each in 22 CHF patients under random, crossover, and DBT conditions, and PSG tests, exercise tests, observation of heart failure symptoms, etc. were compared.
[0016]
As a result, nighttime oxygen therapy improved CSR and improved the maximum oxygen intake, which is an index of exercise tolerance. No significant improvement was observed in daytime heart failure symptoms (Non-patent Document 2).
[0017]
CSR impairs sleep, causing somnolence and cognitive impairment during the day. CSR is an independent prognostic factor. Eleven patients with CHF under random, crossover, and DBT conditions were given oxygen therapy and air inhalation for 4 weeks each, and PSG tests and urinary catecholamine tests as indicators of sympathetic activity were compared. As a result, nighttime oxygen therapy improved CSR and decreased the amount of urinary noradrenaline. No significant improvement was observed in daytime heart failure symptoms (Non-patent Document 3).
[0018]
Home oxygen therapy was introduced into CHF patients, and the minimum amount of exercise to be aware of dyspnea at work before and 1 month after introduction was determined by the SAS (Specific Activity Scale) interview and hospitalization frequency due to heart failure exacerbation before home oxygen therapy introduction We compared hospitalization frequency for one year after introduction. As a result, SAS improved from 2.5 ± 0.9 to 3.3 ± 1.0METs one month before and after the introduction of home oxygen therapy, and the hospitalization frequency decreased significantly from 1.2 ± 1.3 to 0.8 ± 1.2 one year before and after the introduction. (Non-Patent Document 4).
[0019]
As described above, CHF merges CSR at a significant rate, which causes nighttime hypoxia and sleep disturbance due to wakefulness, resulting in reduced exercise tolerance in CHF patients. On the other hand, oxygen therapy is effective in improving CSR and can improve exercise tolerance of CHF patients with CSR.
[0020]
Furthermore, by performing home oxygen therapy in which the above oxygen therapy is performed at home, it becomes possible to continue oxygen therapy for a long period of time under a low economic and social burden without the need for hospitalization. And the accompanying improvement in exercise tolerance of CHF patients can be performed more reliably with less burden.
[0021]
[Non-Patent Document 1]
Increased Mortality Associated with Cheyne-Strokes Respiration in Patients with Congestive Heart Hally PJ & Zuberi-Khokhar NS: Am J Respir Crit Care Med Vol 153, 272-276, 1996.
[0022]
[Non-Patent Document 2]
Improvement of Exercise Capacity With Treatment of Cheyne-Stokes Respiration in Patients With Congestive Heart Failure Andreas S et al: JACC Vol 27 (6), 1486-90, 1996.
[0023]
[Non-Patent Document 3]
Effect of Oxygen on Sleep Quality, Cognitive Function and Sympathetic Activity in Patients With Chronic Heart Failure and Chyene-Stokes Respiration Staniforth AD et al: Eur Heart J Vol 19, 922-928, 1998.
[0024]
[Non-Patent Document 4]
Effects of Home Oxygen Therapy on Patients With Chronic Heart Failure R. Kojima, M. Nakatani, et al: JAC Vol38, 81-86, 2001.
[0025]
[Problems to be solved by the invention]
As described above, it is known that it is effective to perform oxygen therapy, particularly home oxygen therapy, particularly for a CHF patient with CSR.
[0026]
However, it is also known that there are patients who are not effective in oxygen therapy among patients with CHF who are associated with CSR, and those who have CSR with CHF in which this oxygen therapy is effective, and oxygen therapy is not effective. A method for discriminating a patient with CHF associated with CSR without depending on oxygen therapy has not been known.
[0027]
Therefore, when a medical institution treats a patient with CHF, first, it is checked whether or not the CHF patient has a CSR, and if it has, the oxygen therapy is carried out without confirming the effectiveness. There was no other skill. As a result, it is inevitable that oxygen therapy is performed on CHF patients in spite of the fact that there is no therapeutic effect, resulting in medical economic loss, and oxygen therapy that truly requires oxygen therapy. There is also a risk that the application of oxygen therapy to a CHF patient with CSR is effective.
[0028]
In addition, it is a problem related to the above-mentioned prior art, “a method for discriminating between a CSR-combined CHF patient in which oxygen therapy is effective and a CSR-combined CHF patient in which oxygen therapy is not effective, regardless of the implementation of oxygen therapy Needless to say, no solution is shown in any of Non-Patent Document 1 to Non-Patent Document 4 described above.
[0029]
This invention is made | formed in view of said situation, Comprising: The CSR combined CHF patient with which this oxygen therapy is effective, and the CSR combined CHF patient with no effect without actually performing oxygen therapy As a result, it is possible to effectively perform oxygen therapy on a CHF patient with CSR who truly needs oxygen therapy. The purpose is to provide a method for supporting the implementation of therapy.
[0030]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, the present invention provides a method for predicting the therapeutic effect of oxygen therapy and a method for supporting the implementation of oxygen therapy having the configurations described in 1) to 8) below.
[0031]
1) A method for predicting the therapeutic effect of oxygen therapy for predicting the therapeutic effect of individual patients with the effect of oxygen therapy on chronic heart failure patients,
(1) a step of simultaneously measuring and recording information representing an respiratory state of an examinee chronic heart failure patient in sleep and an electrocardiogram waveform over a predetermined time;
(2) identifying a section of the measurement record when the patient is in a central hypopnea state or a central apnea state based on information representing the measured and recorded respiratory state;
(3) a step of extracting a predetermined feature point from the electrocardiogram waveform included in the specified measurement recording section and calculating the total value by totaling the extracted feature point by a predetermined aggregation method;
(4) A method for predicting the therapeutic effect of oxygen therapy, comprising the step of predicting the therapeutic effect for the subject patient based on the calculated total value.
[0032]
2) The method for predicting the therapeutic effect of oxygen therapy according to 1), wherein the total value includes at least one total value among the total values described in (a) to (sa) below.
(A) Total number of normal heartbeats.
(B) Total number of supraventricular extrasystoles.
(C) Total number of ventricular extrasystoles.
(D) Total number of bradycardia.
(E) Total number of tachycardia.
(F) The maximum value of “each heart rate in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(G) The minimum value of “each heart rate in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(H) The average value of “each heart rate in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(G) The maximum value of “each RR interval in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(G) The minimum value of “each RR interval in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(S) Average value of “each RR interval in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
[0033]
3) The above-mentioned “total number of supraventricular extrasystoles” is “the total number of supraventricular extrasystoles among one, two, three, four, more than two, and three steps. 2) The method for predicting the therapeutic effect of oxygen therapy according to 2).
[0034]
4) The “total number of ventricular extrasystoles” is “the total number of ventricular extrasystoles among one, two, three, four, more than two, and three steps”. 2. The method for predicting the therapeutic effect of oxygen therapy according to 2) or 3), wherein
[0035]
5) Characteristic values that have a significant correlation with the therapeutic effects of oxygen therapy on individual patients in order to assist medical professionals who should determine whether or not to perform oxygen therapy for patients with chronic heart failure In the method for supporting the execution of oxygen therapy, the method includes the step of displaying using a predetermined display means.
The characteristic value is
The information indicating the respiratory state of the subject chronic heart failure patient in sleep and the electrocardiogram waveform are simultaneously measured and recorded over a predetermined time, and the patient performs central hypopnea based on the information indicating the measured respiratory state. The section of the measurement record when in a state or a central apnea state is specified, a predetermined feature point is extracted from an electrocardiogram waveform included in the specified measurement record section, and the extraction is performed by a predetermined aggregation method An oxygen therapy implementation support method, characterized in that the calculated feature points are totaled and calculated.
[0036]
6) In order to assist medical professionals who should determine whether or not to perform oxygen therapy for patients with chronic heart failure, characteristic values that can be used to predict the therapeutic effect when oxygen therapy is performed on individual patients are specified. In the method for supporting the execution of oxygen therapy, comprising the step of displaying using a display means,
The characteristic value is
The information indicating the respiratory state of the subject chronic heart failure patient in sleep and the electrocardiogram waveform are simultaneously measured and recorded over a predetermined time, and the patient performs central hypopnea based on the information indicating the measured respiratory state. The section of the measurement record when in the state or the central apnea state is specified, and the characteristic values described in (a) to (sa) below are calculated from the electrocardiogram waveform included in the specified measurement record section. A method for supporting the implementation of oxygen therapy, comprising at least one of the characteristic values.
(A) Total number of normal heartbeats.
(B) Total number of supraventricular extrasystoles.
(C) Total number of ventricular extrasystoles.
(D) Total number of bradycardia.
(E) Total number of tachycardia.
(F) The maximum value of “each heart rate in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(G) The minimum value of “each heart rate in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(H) The average value of “each heart rate in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(G) The maximum value of “each RR interval in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(G) The minimum value of “each RR interval in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(S) Average value of “each RR interval in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
[0037]
7) The above-mentioned “total number of supraventricular extrasystoles” is “the total number of supraventricular extrasystoles of any one of two, three, and three-stage pulse. 6) The method for supporting the implementation of oxygen therapy according to 6).
[0038]
8) The “total number of ventricular extrasystoles” is “the total number of ventricular extrasystoles among one, two, three, four, more than two, and three steps”. 6. The method for supporting the implementation of oxygen therapy according to 6) or 7), wherein
[0039]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a method for predicting the effect of oxygen therapy, which is a preferred example according to the embodiment of the present invention, will be described with reference to FIGS. 1 to 3.
[0040]
FIG. 1 is a block diagram of a biological information monitoring system used in this embodiment, FIG. 2 is an example of an electrocardiogram waveform measured using the system of FIG. 1, and FIG. 3 is a procedure for stratifying patients in this embodiment. It is a flowchart.
[0041]
[Features of biological information monitoring system]
As described above, conventionally, a method for discriminating between a CSR-combined CHF patient in which oxygen therapy is effective and a CSR-combined CHF patient in which oxygen therapy is not effective without actually performing oxygen therapy has not been known. As a result, the problems of great medical economic loss and loss of patient treatment opportunities have not been solved.
[0042]
Therefore, as a result of intensive efforts to solve the above-mentioned problems, the present inventor obtained the following knowledge by examining the treatment data regarding a large number of patients with oxygen therapy and making various studies. .
[0043]
That is, “(1) The ECG waveform of this patient during a central apnea period or a central hypopnea period, which is an apnea section or a hypopnea section that appears when a CHF patient with CSR is in a chain-Stokes breathing state. And (2) the therapeutic effect of oxygen therapy when oxygen therapy is performed on this patient has a significant correlation ”.
[0044]
Therefore, the appropriate feature points are extracted from the ECG waveform of the patient during the central apnea period and the central hypopnea period of the above-mentioned CSR-combined CHF patient, and the extracted feature points are totalized by an appropriate method. If the effect of oxygen therapy is determined based on the results of this aggregation, it is possible to select patients who are effective in oxygen therapy among CSR-combined CHF patients, or at least the ratio of patients who are effective in oxygen therapy. The inventors have found that it is possible to carry out screening of patients for the effects of oxygen therapy to enhance.
[0045]
Based on the above knowledge, the biological information monitoring system of the present embodiment, which is a system proposed by the present inventor for executing the above patient selection or patient screening, has the following features. Yes.
(1) A patient's electrocardiogram waveform and a waveform representing a respiratory state (specifically, a respiratory effort detection waveform, a respiratory airflow detection waveform, etc., as described below) can be measured simultaneously.
(2) It is possible to specify the central apnea section and the central hypopnea section of the patient from the measured waveform representing the respiratory state.
(3) From the patient's electrocardiogram waveform in the identified central apnea section and central hypopnea section, extract the predetermined feature points in advance, and sum up by the predetermined summation method in the same way Aggregated values can be generated.
(4) The above-mentioned total value is displayed using a predetermined display means, and the medical staff such as a doctor can predict the effect when oxygen therapy is performed on this patient based on the displayed contents. I can do it.
[0046]
Furthermore, as a preferable modification, the apparatus may be configured to automatically predict the effect when oxygen therapy is performed on the patient using the above-described total value.
[0047]
Hereinafter, a more detailed configuration of the biological information monitoring system suitable for carrying out the method for predicting the effect of oxygen therapy according to the present embodiment will be described.
[0048]
[Configuration of biological information monitoring system]
As shown in the configuration diagram of FIG. 1, the biological information monitoring system 1 is roughly composed of a biological information monitor 2 and a biological information analysis device 3.
[0049]
Furthermore, the biological information monitor 2 includes an amplifier unit 2b, a writing unit 2c, an IC card 2e that is detachably disposed inside the main body 2a, an outside of the main body 2a, and a lead wire. An electrode part 2d connected to the amplifier part 2b via the lead, and a respiratory airflow sensor, a chest-abdominal belt sensor, blood oxygen, which are connected to the amplifier part 2b outside the main body 2a but not shown, though not shown A saturation concentration sensor. In addition, you may comprise so that it may have sensors other than the above-mentioned.
[0050]
The main body 2a has a light and small housing structure and can be easily attached to the patient's waist using a belt or the like. As a result, the following measurements are performed on the sleeping patient. Easy to do.
[0051]
The amplifier unit 2b supplies power to each of the sensor units connected to the amplifier unit 2b via lead wires, receives sensor signals from the sensor units, and executes predetermined amplification and A / D conversion. Thus, it has a function of outputting the converted signal to the writing unit 2c.
[0052]
The writing unit 2c has a function of recording the digital signal input from the amplifier unit 2b on the IC card 2e. The IC card 2e is a recording medium capable of writing / reading digital signals, and is configured to be detachable from the main body 2a, so that the IC card 2e after the patient data is measured and written can be used as described above. Can be removed from the biological information monitor main body 2a and attached to the biological information analyzing apparatus 3 described later, and analysis of the measured data can be executed.
[0053]
The electrode unit 2d is a sensor for attaching each electrode of the electrode unit 2d to the skin surface of a predetermined site of the patient and acquiring an electrocardiogram waveform of the patient. The respiratory airflow sensor is a sensor for measuring the presence / absence and strength of an airflow caused by the patient's breathing by being attached to the vicinity of the patient's nasal cavity and measuring the intensity of the airflow.
[0054]
The chest and abdominal belt sensor is worn around the chest and abdomen around the patient. When the chest and / or abdomen is repeatedly expanded and contracted as the patient breathes, the chest and abdomen belt sensor expands and contracts. This sensor detects the movement of the rib cage and / or the abdomen, and as a result, detects the patient's respiratory effort.
[0055]
The blood oxygen saturation sensor is a sensor for continuously and non-invasively measuring the oxygenation level and pulse rate of arterial blood. In other words, the measurement can be performed simply by putting the scissors-like sensor part between the fingertips of the patient and illuminating the fingertips, so there is no need for blood collection, the operation is easy and the results are immediately known, and It is not necessary. The measurement principle is to calculate arterial oxygen saturation by measuring the amount of transmitted light by applying two types of light with different wavelengths to the finger. The arterial blood identification changes in accordance with the pulse. Focusing on the components, the oxygen saturation is calculated using the fact that oxygen hemoglobin has different transmittances for two types of light.
[0056]
Next, the biological information analysis apparatus 3 which is another large structural unit constituting the biological information monitoring system 1 will be described.
[0057]
As shown in the configuration diagram of FIG. 1, the biological information analyzing apparatus 3 includes a reader 3a configured so that the above-described IC card 2e can be attached and detached, a main processing device 3b connected to the reader 3a, and the main processing device 3b. A monitor 3c connected to the main processor 3b, an editor 3d connected to the main processor 3b, and a printer 3e connected to the main processor 3b.
[0058]
The reader 3a has a function of reading data recorded therein from the mounted IC card 2e and outputting it to the main processing device 3b.
[0059]
In the living body information monitoring system 1 of the present embodiment, the point that the IC card 2e is used as a medium for recording data measured from the patient is as described above. Of course, it is possible to use a medium such as a flash memory, an MO disk, an optical disk, a magnetic tape, or a magnetic diskette.
[0060]
Returning to the description of the configuration again, the main processing device 3b executes processing according to a predetermined processing procedure using various biological information of the patient input from the reader 3a, and displays, records, and transmits the processing result. Therefore, it has a function of outputting. The actual processing procedure will be described later.
[0061]
Specifically, the main processing device 3b uses a configuration in which a dedicated program is installed in a general-purpose personal computer. Of course, it can also be realized as a dedicated hardware configuration.
[0062]
The editor 3d is configured to be used for editing biological information input from the reader 3a to the main processing device 3b. For example, a predetermined medical worker visually observes biological information measured over a long period of time such as 24 hours. It is possible to confirm and select a section for information processing.
[0063]
For this purpose, the editor 3d includes input means such as a pad and a keyboard, and selection means.
[0064]
Further, the monitor 3c is configured so that the main processing device 3b can detect from the biological information input to the main processing device 3b, the data obtained by editing the biological information using the editor 3d, or the electrocardiogram waveform among these biological information. It has a function of displaying the result of extracting and summing up predetermined feature points. As will be described later, by using the total value displayed on the monitor 3c, it is possible to perform prediction when a medical worker, particularly a doctor, performs oxygen therapy on the patient.
[0065]
The printer 3e has a function of printing information that can be displayed on the monitor 3c on a paper medium in response to an input from the main processing device 3b.
[0066]
[Identification of central apnea section and central hypopnea section]
Next, a method for identifying the central apnea section and the central hypopnea section of the patient from the series of measurement sections in the information processing executed by the main processing device 3b will be described.
[0067]
Among the biological information read out from the IC card 2e by the reader 3a and output to the main processing device 3b, the presence / absence of the airflow due to the breathing of the patient, information on the strength (hereinafter referred to as airflow information) measured by the respiratory airflow sensor, It has been explained above that it contains respiratory effort information that can be detected from the movement of the thorax of this patient, measured by a thoracoabdominal belt sensor.
[0068]
Therefore, in order to specify the central apnea section and the central hypopnea section that occur with Chain-Stokes breathing, two threshold values, large and small, are set in advance for the airflow information level and the respiratory effort information level, respectively. An area where both the airflow information level and the respiratory effort information level are below a small threshold value is defined as a central apnea section, and an area exceeding the small threshold value but below the large threshold value is defined as a central area. Type hypopnea section.
[0069]
The method for specifying the central hypopnea section and the central apnea section using the airflow information level and the respiratory effort information level can be used in addition to the above two thresholds. Further, in the subsequent processing, it is also possible to adopt a configuration in which feature points are extracted and aggregated using an electrocardiogram waveform only in the central apnea section or the central hypopnea section.
[0070]
By the way, in the obstructive apnea section and the obstructive hypopnea section (for example, appearing in sleep apnea syndrome caused by airway obstruction) compared with the central apnea section and the central hypopnea section, the level of the airflow information However, since the patient's respiratory effort is being performed, the level of the respiratory effort information does not fall below the predetermined threshold.
[0071]
[Extraction and tabulation of feature points from ECG waveform]
Next, the point that the main processing device 3b extracts and summarizes the feature points from the patient's electrocardiogram waveform included in the biological information read from the IC card 2e will be described.
[0072]
It should be noted that a portion of the electrocardiogram waveform to be extracted can be selected and used for extraction by a predetermined medical worker in advance from the entire measurement section using the editor 3e.
[0073]
The main processing device 3b performs extraction and tabulation from the electrocardiogram waveform for at least one of the following tabulated values.
(A) Total number of normal heartbeats.
(B) Total number of supraventricular extrasystoles.
(C) Total number of ventricular extrasystoles.
(D) Total number of bradycardia.
(E) Total number of tachycardia.
(F) When there are a plurality of measurement intervals identified in the above procedure (in the above configuration example, a central apnea interval and a central hypopnea interval; the same applies hereinafter), “in a plurality of specified measurement intervals Maximum value of each heart rate.
(G) The minimum value of “each heart rate in a plurality of specified measurement intervals” when there are a plurality of measurement intervals specified in the above procedure.
(H) Average value of “each heart rate in a plurality of specified measurement intervals” when there are a plurality of measurement intervals specified in the above procedure.
(G) The maximum value of “each RR interval in a plurality of specified measurement sections” when there are a plurality of measurement sections specified by the above procedure.
(G) The minimum value of “each RR interval in a plurality of specified measurement sections” when there are a plurality of measurement sections specified by the above procedure.
(S) Average value of “each RR interval in a plurality of specified measurement sections” when there are a plurality of measurement sections specified in the above procedure.
[0074]
In addition, the above-mentioned “total number of supraventricular extrasystoles” is “the number of supraventricular extrasystoles in any one of two, three, and three-stage pulse. You may comprise so that it may be "total number." Furthermore, the “total number of ventricular premature contractions” is “the total number of ventricular premature contractions of any one of two, three, and more than one, two, three, four, or more.” You may comprise.
[0075]
Here, “supraventricular extrasystole” and “ventricular extrasystole” are both one type of arrhythmia, bradycardia is a pulse with a heart rate lower than normal, and tachycardia is higher than normal. Heart rate pulse, RR interval is the interval between adjacent R waveforms in the electrocardiogram waveform, two-shot, three-shot, four-shot or more, arrhythmia appears twice, three times, four times or more in succession State, 2-stage pulse refers to a state where normal heartbeats and arrhythmia appear alternately, and 3-stage pulse refers to a state where one arrhythmia appears between two normal heartbeats.
[0076]
FIG. 2 illustrates an example of an electrocardiogram waveform in a state of triple firing, two-stage pulse, and three-stage pulse.
[0077]
In addition, a configuration for executing extraction of these feature points and calculation of a total value according to a predetermined total procedure can be easily realized by using a known technique.
[0078]
That is, in the published books Okajima, Hashiguchi: Reliability of the electrocardiogram system (1990, IPC Co., Ltd.), particularly from page 142 to page 153 and from page 268 to page 300, predetermined from the electrocardiogram waveform A configuration for extracting the feature points is described in detail.
[0079]
The outline is that noise is first removed from the measured electrocardiogram waveform, the QRS group is detected by a differentiation method or the like, the target QRS group obtained by this is classified into a group of similar waveforms, and each group is normal. It is roughly divided into the degree of ventricular extrasystole, and by adding the information of the RR interval to it, finally, normal, ventricular extrasystole (single, two, more, more polymorphism), Normal early contraction (form of QRS group is similar to normal, but RR interval is narrow, usually sinus arrhythmia or supraventricular arrhythmia), and others (including noise) are generally classified into about 4 groups Is.
[0080]
As a method of performing classification based on the waveform form as described above, two methods, one based on pattern matching and the other based on feature extraction, are mainly used (supra, pages 286 to 287).
[0081]
That is, according to the method as described above, the measured waveform is classified into normal heartbeat, supraventricular extrasystole, etc., and then counted for each of the above-described central apnea section and central hypopnea section, Each aggregated value can be calculated. When classifying as bradycardia and tachycardia, for example, the case where the heart rate is 60 beats / minute or less is referred to as bradycardia, and the case where the heart rate is also 100 beats / minute or more is referred to as tachycardia. .
[0082]
The main processing device 3b may be configured to total all the above-described total values, or may be configured to total only one or a plurality of total values included in each total value. Furthermore, it is also possible to configure so as to make a total other than those described above.
[0083]
[Procedure from patient selection to oxygen therapy]
Next, including the procedure for predicting the effect of oxygen therapy using the biological information monitoring system 1 described above, the procedure for selecting a patient with effective oxygen therapy from the CHF patient with CSR and performing oxygen therapy Will be explained.
[0084]
As the above procedure, for example, as shown in the flow of FIG. 3A, screening of patients using blood oxygen saturation concentration (step S1), prediction of the effect of oxygen therapy (step S2), and oxygen therapy (Step S3) can be configured to be included.
[0085]
Alternatively, as shown in the flow shown in FIG. 3B, it is configured to include the prediction of the effect of oxygen therapy (step S11) and the execution of oxygen therapy (step S12) without performing the above screening. Is also possible.
[0086]
In the following description, the description will be made mainly along the procedure based on the flow illustrated in FIG.
[0087]
[Screening patients using blood oxygen saturation (Step S1)]
In CHF, 40% of them are said to be combined with Chain-Stokes breathing (CSR, temporary increase or decrease in respiratory airflow, and subsequent central apnea or hypopnea). As explained.
[0088]
And it is known that in the state of apnea or hypopnea in the chain-Stokes breathing, the blood oxygen saturation concentration of the patient is lower than the normal value. Therefore, the blood oxygen saturation level of a patient is continuously measured over a certain measurement period, for example, 24 hours. If this decrease in blood oxygen saturation level is observed during the measurement period, chain-Stokes breathing is suspected. As a patient, a method for screening a patient is effective.
[0089]
Here, as a configuration for measuring the blood oxygen saturation concentration, a “printer-compatible portable pulse oximeter” that was previously developed and marketed by the present applicant (trade name: PULSOX-SP, medical device manufacturing) It is also conceivable to use an approval number (04B) No. 0918) (not shown).
[0090]
The above-mentioned PULSOX-SP is a publicly known document, “Pulsox Portable Pulse Oximeter PULSOX-SP” (published by Teijin Limited Home Health Care Division), which is a publicly available document. It is a device for continuously and non-invasively measuring the pulse rate. In other words, the measurement can be performed simply by putting the scissors-like sensor part between the fingertips of the patient and illuminating the fingertips, so there is no need for blood collection, the operation is easy and the results are immediately known, and It is not necessary. The measurement principle is to calculate arterial oxygen saturation by measuring the amount of transmitted light by applying two types of light with different wavelengths to the finger. The arterial blood identification changes in accordance with the pulse. Focusing on the components, the oxygen saturation is calculated using the fact that oxygen hemoglobin has different transmittances for two types of light.
[0091]
As the patient population for selecting the above-mentioned patients whose blood oxygen saturation level is to be measured, that is, the patients who are to be subjected to prediction of oxygen therapy, patients with chronic heart failure, patients with suspected chronic heart failure, or patients with chronic heart failure Among these, patients suspected of having a CSR merger are desirable, or it may be possible to conduct a random screening for group patients.
[0092]
In the flow shown in FIG. 3 (B), when screening using oxygen saturation concentration in blood is not performed, the effect of oxygen therapy using the biological information monitoring system 1 is first predicted. The blood oxygen saturation concentration of the patient may be measured using a blood oxygen saturation concentration sensor attached to the biological information monitoring system 1.
[0093]
In addition, since a decrease in blood oxygen saturation level is also observed in symptoms other than chain-Stokes breathing, the blood oxygen saturation level measurement step described above merely screens patients suspected of having chain-Stokes breathing. Needless to say, there is no point.
[0094]
[Effect prediction of oxygen therapy (step S2)]
Next, the effect of oxygen therapy is predicted using the above-described biological information monitoring system 1 for a patient whose blood oxygen saturation concentration is decreased by the above-described steps and the occurrence of chain-Stokes respiration is suspected. The procedure for performing is described.
[0095]
The target patient to be predicted visits a medical institution, and a medical worker wears the biological information monitor 2 on the patient. The measurement may be started when the medical institution is mounted, or may be started when the patient who has returned home turns on a switch attached to the biological information monitor 2 by himself / herself.
[0096]
When the measurement starts, the above-described information such as an electrocardiogram waveform and respiratory airflow information is measured over a predetermined measurement period, for example, 24 hours, and is recorded on the IC card 2e mounted inside the biological information monitor 2. .
[0097]
When the measurement and recording are completed, the patient visits the medical institution again with the biological information monitor 2 attached. After confirming the mounting state of the patient's biological information monitor 2, the medical worker removes the biological information monitor 2 from the patient, removes the IC card 2e, and mounts it on the reader 3a of the biological information analyzer 3.
[0098]
Further, the medical worker selects an appropriate measurement section to be used for prediction of oxygen therapy using the editor 3e while confirming the biological information measured from the patient displayed on the monitor 3c.
[0099]
Then, the main processing device 3b selects the central type apnea section and the hypopnea section from the selected measurement section, that is, both the respiratory airflow information and the respiratory effort information have predetermined thresholds. Identify based on below.
[0100]
Further, the main processing device 3b extracts a predetermined feature point, for example, a normal heart rate, from the above identified central apnea and hypopnea sections, and totals the same by a predetermined counting method. For example, the total number of normal heartbeats is generated and output to the monitor 3c to display the total value.
[0101]
Based on the result of knowing the total value displayed on the monitor 3c, the health care worker makes a prediction judgment of the effect when oxygen therapy is performed on the patient, and performs oxygen therapy on the patient. Determine whether or not.
[0102]
[Execution of oxygen therapy (step S3)]
If oxygen therapy is effective, oxygen therapy is performed on a patient who is judged by a medical staff. When home oxygen therapy is selected, where oxygen enriched gas is supplied from the oxygen concentrator at home, the oxygen concentrator is installed at the patient's home, and in many cases the patient is sent to a medical institution for a short period of time. After being hospitalized and receiving guidance on home oxygen therapy, home oxygen therapy is started at home.
[0103]
Here, as described above, the oxygen concentrator is an apparatus for generating oxygen-enriched gas from the air in the patient's home and supplying it for breathing of the patient through a tubular member called a cannula. It can be configured on the basis. That is, an outline of a typical configuration and operation for exhibiting the oxygen enrichment function (the function of increasing the oxygen concentration of the air inhaled by the patient to 90%, that is, the oxygen enrichment function) of the oxygen concentrator is (1 ) One or more adsorption cylinders filled with an adsorbent capable of selectively adsorbing nitrogen in the air are placed in the oxygen concentrator, and (2) from the compressor through the flow path switching valve Compressed air is supplied to the leverage cylinder, and (3) oxygen-containing gas that has not been adsorbed by the adsorption cylinder, that is, oxygen-enriched air, is stored in a surge tank. (5) Humidifier is used and (6) is supplied to the patient via the cannula.
[0104]
[Modification of this embodiment]
The method for predicting the effect of oxygen therapy according to the present embodiment can be variously modified and appropriately changed in addition to the above-described configuration.
[0105]
For example, as a modification of the present embodiment, the main processing device 3b described above not only generates the above-mentioned total value, but also predicts the therapeutic effect when oxygen therapy is performed on this patient using the generated total value. The predicted result may be displayed on the monitor 3c. This configuration helps doctors and other medical professionals to judge and prevents misreading of the display, etc., and it is possible for people other than medical professionals to know the prediction results and use them as a guide And various benefits are obtained.
[0106]
As a specific procedure for performing the prediction, for example, the following procedure can be considered.
[0107]
The main processing device 3b extracts feature points from the electrocardiogram waveform, and generates, for example, “the total number of normal heartbeats in the central apnea section and the central hypopnea section” as a total value.
[0108]
Therefore, the threshold value of this total value is determined in advance, and the therapeutic effect of oxygen therapy can be predicted by determining whether the total value generated from the patient's biological information exceeds this threshold value.
[0109]
Alternatively, for a plurality of types of aggregate values, after determining whether or not each predetermined threshold is exceeded, a prediction result may be derived using a logical operation value of these determination values, for example, logical product or logical sum. Is possible. Other configurations are of course possible.
[0110]
【The invention's effect】
As described above, the present invention can easily discriminate between a CSR-combined CHF patient in which this oxygen therapy is effective and a CSR-combined CHF patient in which the oxygen therapy is ineffective without actually needing to perform oxygen therapy. As a result, the present invention provides a method for predicting the therapeutic effect of oxygen therapy and a method for supporting the implementation of oxygen therapy, which can efficiently perform oxygen therapy for a patient with CHF who really needs oxygen therapy. I can do it.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a biological information monitoring system used in a method for predicting the effect of oxygen therapy, which is a preferred example according to an embodiment of the present invention.
2 is an example of an electrocardiogram waveform measured using the system of FIG.
FIG. 3 is a flowchart showing a procedure for stratifying patients in the method for predicting the effect of oxygen therapy, which is a preferred example according to the embodiment of the present invention;
[Explanation of symbols]
1 Biological information monitoring system
2 Biological information monitor
3 biological information analyzer
3b Main processing unit
3c monitor

Claims (3)

(A)   Means for measuring and recording airflow information relating to the presence or intensity of the subject's respiratory airflow,
  Means for detecting the movement of the body part associated with the respiratory effort of the subject and measuring and recording the respiratory effort information based on the movement; and
  Means for measuring and recording an electrocardiogram waveform of the subject having an electrode that can be attached to the skin surface of the subject
  And a biological information monitor device configured to be able to move the subject in a state of being attached to the outside of the subject's body,
(B)   Receiving means for receiving the airflow information, the respiratory effort information, and the information on the electrocardiogram waveform from the biological information monitor device,
  A measurement interval in which the level of the received airflow information and the level of the respiratory effort information are both lower than a preset threshold is specified as a central apnea interval or a central hypopnea interval, and in the specified interval Processing means for generating at least one characteristic value from among the characteristic values shown in the following (a) to (sa) by using the information of the electrocardiogram waveform, and performing output for display, recording, transmission or printing; as well as,
  Output means for outputting a processing result by the processing means;
  A biological information analysis apparatus comprising:
  A biological information monitoring system comprising:
(A) Total number of normal heartbeats.
(B) Total number of supraventricular extrasystoles.
(C) Total number of ventricular extrasystoles.
(D) Total number of bradycardia.
(E) Total number of tachycardia.
(F) The maximum value of “each heart rate in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(G) The minimum value of “each heart rate in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(H) An average value of “each heart rate in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(G) The maximum value of “each RR interval in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(G) The minimum value of “each RR interval in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.
(S) Average value of “each RR interval in the plurality of specified measurement record sections” when there are a plurality of specified measurement record sections.   The processing means, after generating the at least one characteristic value, predicts a therapeutic effect when oxygen therapy is performed on the subject by determining whether the characteristic value exceeds a preset threshold value. The biological information monitoring system according to claim 1, wherein the prediction result is output to the output unit.   The biological information monitoring device has an IC card configured to be detachable from the biological information monitoring device,
  The biological information monitoring system according to claim 1, wherein the receiving unit includes a unit that allows the IC card to be attached and detached and reads information recorded on the IC card.

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