RU2774258C1 - Method, system and apparatus for determining arterial stiffness - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: method for determining arterial stiffness is implemented by an apparatus containing a control unit, a pump, an outlet valve, a shoulder cuff, a pressure sensor, an apparatus for human-computer interaction, and a communication apparatus. The control unit is in connection with the pump, the pressure sensor, the apparatus for human-computer interaction, and the communication apparatus. The outlet valve is located on the shoulder cuff, which is mechanically connected with the pump, the outlet valve, and the pressure sensor. The communication apparatus is in data exchange connection with a cloud server. Pressure values are therein received from the pressure sensor in the process of increasing or reducing the pressure on the shoulder cuff. A characteristic pressure curve is formed for the time-variant pressure value. The arterial stiffness index is obtained in accordance with the characteristic of the curve segment corresponding to a preset pressure value. The highest and lowest blood pressure values and pulse rate are obtained on the basis of the pressure value. No more than two blood pressure values, the pulse rate and the arterial stiffness index are displayed. The blood pressure values and the degree of hypertension are displayed as a graph in two-dimensional coordinates. Alternatively, the degree of atherosclerosis and the degree of hypertension are displayed as a graph in two-dimensional coordinates. Alternatively, no more than two indicators from the degree of arteriosclerosis and the degree of hypertension, as well as the arterial stiffness index, blood pressure values and the pulse rate are displayed as a multidimensional trend graph. Alternatively, no more than four indicators from the blood pressure values, the pulse rate, the degree of arteriosclerosis and the degree of hypertension are displayed, and the arterial stiffness index is displayed as a dial indicator.

EFFECT: increase in the accuracy of determining arterial stiffness and a more precise arterial stiffness index obtained through a simplified procedure suitable for wide use, so that various parameters can be simultaneously measured and displayed, including the degree of hypertension of the patient, based on the changes in the values of their arterial pressure over time, wherein a point on the graph in two-dimensional coordinates indicates the coordinate position of the values of the highest and lowest blood pressure.

20 cl, 13 dwg, 3 ex

Description

Technical field

[0001] The present invention relates to the field of medical technology and, in particular, to a method, system and device for determining arterial stiffness.

BACKGROUND OF THE INVENTION

[0002] With the constant development of medical technology and people's increased attention to their health status, the use of various medical equipment to determine the relevant physiological parameters has become a common way to determine the health status.

[0003] However, existing devices used to detect arterial stiffness are difficult to operate and give relatively coarse detection results, so they are difficult to popularize and use.

SUMMARY OF THE INVENTION

Technical task

[0004] One of the objectives of the present invention is to: provide a method, system and apparatus for determining arterial stiffness to solve the problem that existing devices used to determine arterial stiffness are difficult to operate and provide relatively rough results. detection. Therefore, these devices are difficult to popularize and use.

Problem solutions

Technical solutions

[0005] To solve the above problem, the first object of the present invention is a method for determining arterial stiffness, which is implemented using an arterial stiffness determining device. The device for determining arterial stiffness contains a shoulder cuff, a pressure sensor and a human-computer interface device.

[0006] A method for determining arterial stiffness includes:

[0007] obtaining the pressure value of the pressure sensor in the process of increasing or decreasing the pressure of the shoulder cuff;

[0008] generating a pressure characteristic curve for a time-varying pressure value;

[0009] obtaining an arterial stiffness index according to a characteristic of a curve segment corresponding to a predetermined pressure value on the pressure characteristic curve;

[0010] deriving blood pressure and heart rate values from the pressure value, the blood pressure values including the highest blood pressure value and the lowest blood pressure value; and

[0011] displaying at most two of the blood pressure values, and displaying the pulse rate and arterial stiffness index by means of a human-computer interface device.

[0012] A pressure characteristic curve is generated for a time-varying pressure value.

[0013] A second aspect of the present invention is an arterial stiffness detection system that is implemented using an arterial stiffness detection device. The arterial stiffness detection device includes a shoulder cuff, a pressure sensor, and a human-computer interface device. Arterial stiffness indication system includes:

[0014] a first data acquisition module, configured to obtain a pressure value of the pressure sensor in the process of increasing or decreasing the pressure of the shoulder cuff;

[0015] a second data acquisition module, configured to generate a pressure characteristic curve for a time-varying pressure value;

[0016] a third data acquisition module, configured to obtain an arterial stiffness index according to a characteristic of a curve segment corresponding to a predetermined pressure value on the pressure characteristic curve;

[0017] a fourth data acquisition module, configured to obtain blood pressure values and pulse rate according to the pressure value, the blood pressure values including the highest blood pressure value and the lowest blood pressure value; and

[0018] a display module configured to display at most two of the blood pressure values and display a pulse rate and an arterial stiffness index through a human-computer interface device.

[0019] A characteristic pressure curve is generated for a pressure value changing over time.

[0020] A third aspect of the present invention is an arterial stiffness detection device, comprising a control unit, a pump, an exhaust valve, a shoulder cuff, a pressure transducer, a human-computer interface device, and a communication device.

[0021] The control unit is associated with a pump, a pressure sensor, a human-computer interface device, and a communication device, respectively. The exhaust valve is located on the shoulder cuff; the shoulder cuff is mechanically connected to the pump, outlet valve and pressure sensor, respectively; and the communication device is in communication with the ability to communicate with the cloud server.

[0022] The control unit is configured to perform the steps of the above method.

[0023] A fourth aspect of the present invention is a computer-readable storage medium. A computer-readable storage medium stores a computer-readable instruction. The machine readable instruction, when executed by its processor, implements the steps of the above method.

[0024] By means of an arterial stiffness detection device comprising a shoulder cuff, a pressure sensor, and a human-computer interface device, in the embodiments of the present invention, the value of the pressure applied by the artery to the pressure sensor in the process of increasing or decreasing the pressure of the shoulder cuff is obtained, a pressure characteristic curve is obtained for time-varying pressure values, and an arterial stiffness index is obtained in accordance with a characteristic of a curve segment corresponding to a predetermined pressure value on the pressure characteristic curve. So the procedure is simple, a relatively accurate arterial stiffness index can be obtained, and the accuracy of arterial stiffness can be effectively improved. Blood pressure and pulse rate values are obtained according to the pressure value, while no more than two of the blood pressure values, pulse rate and arterial stiffness index are displayed by a human-computer interface device, so that various parameters can be simultaneously measured and displayed, and examples implementations are suitable for wide promotion and use.

[0025] It can be understood that the positive effects of the above second to fourth objects may refer to the respective descriptions of the first object, and repeated descriptions are omitted here.

BRIEF DESCRIPTION OF THE FIGURES

[0026] In order to more clearly describe the technical solutions in the embodiments of the present invention, the following will briefly describe the figures necessary to understand the embodiments of the invention or to illustrate the prior art. Obviously, the figures listed below are only some examples of the implementation of the present invention. Those skilled in the art can also obtain other images in accordance with the provided figures without doing any creative work.

[0027] Figure 1 is a flowchart of the method for determining arterial stiffness described as Example I of the present invention.

[0028] In FIG. 2-9 are schematic representations of a display interface for Embodiment I of the present invention;

[0029] FIG. 10 is a block diagram of the arterial stiffness detection system described as Example II of the present invention;

[0030] FIG. 11-13 are block diagrams of the arterial stiffness determination apparatus described as Embodiment III of the present invention.

DESCRIPTION OF EXAMPLES OF CARRYING OUT THE INVENTION

[0031] In order for those skilled in the art to better understand the solutions of the present invention, the technical solutions in the exemplary embodiments of the present invention will be described in detail below in conjunction with the figures. Obviously, the exemplary embodiments described herein are only a part of the exemplary embodiments of the present invention and not all of the exemplary embodiments. Based on the described embodiments, all other embodiments obtained by those skilled in the art without creative work shall fall within the protection scope of the present invention.

[0032] The term "including" and any variations thereof in the description and claims of the present disclosure and in the above drawings are intended to cover non-exclusive inclusions. In addition, terms such as "first", "second" and "third" are used to distinguish between different objects, not to describe a particular order.

[0033] Example I

[0034] The present embodiment of the invention is a method for determining arterial stiffness, which is implemented on the basis of the device for determining arterial stiffness. The arterial stiffness detection device includes a control unit, a pump, an exhaust valve, a shoulder cuff, a pressure sensor, a temperature sensor, a humidity sensor, a barometer, a human-computer interface device, a communication device, a motion sensor, and a device for determining the position of the shoulder cuff. The control unit includes a shoulder cuff pressure control unit for controlling the pump speed and a data processing unit having a data processing function. The outlet valve is located on the shoulder cuff.

[0035] As shown in FIG. 1, the method for determining arterial stiffness provided by the present embodiment includes the following operations performed by the control unit.

[0036] In step S101, the pressure value of the pressure sensor is obtained in the process of increasing or decreasing the pressure of the shoulder cuff.

[0037] In step S102, a pressure characteristic curve is generated for the time-varying pressure value.

[0038] In some cases, the amplitude of the artery usually regularly changes during the vibration of the artery. Accordingly, the pressure value detected by the pressure sensor will also change accordingly. Obtaining a pressure characteristic curve for a time-varying pressure value is advantageous for intuitive observation of arterial vibration to effectively assess arterial stiffness.

[0039] In the exemplary embodiment, the method includes the following before step S102.

[0040] Step S100, in which, in the process of pressurizing the shoulder cuff, a pulse width modulation signal is output in accordance with the current pressure value to control the rotation speed of the pump or the opening/closing degree of the exhaust valve to correct the air inlet speed of the shoulder cuff to correct the pressure value at the next moment.

[0041] In a specific application, the data processing unit generates a pulse width modulation signal in accordance with the pressure value, and then the cuff pressure control unit controls the pump rotation speed or the degree of opening/closing of the exhaust valve in accordance with the pulse width modulation signal to realize shoulder cuff air intake speed control.

[0042] In a specific application, by adding and adjusting the air suction speed at the current moment to correct the pressure value at the next moment, the pressure value measured by the pressure sensor can be changed more smoothly in time, so the pressure characteristic curve becomes smoother.

[0043] In one embodiment of the invention, step S102 includes:

[0044] step S1021, in which, taking the pressure value as the dependent variable, a curve fitting is performed to obtain a pressure characteristic curve for the time-varying pressure value.

[0045] In a particular application, a least squares method may be used to perform a curve fitting to obtain a characteristic pressure curve.

[0046] In step S103, an arterial stiffness index is obtained according to a characteristic of a curve segment corresponding to a predetermined pressure value on the pressure characteristic curve.

[0047] In a specific application, the upper limit for estimating the predetermined pressure value is the maximum pressure value detected by the pressure sensor, and the lower limit for estimating is the minimum pressure value detected by the pressure sensor. The predetermined pressure value can be any value between the minimum and maximum pressure values according to actual requirements.

[0048] In one embodiment, step S103 includes:

[0049] step S1031, where the arterial stiffness index is obtained based on the constant A and the first coefficient. The first coefficient is a coefficient related to the length of time corresponding to a predetermined pressure value.

[0050] In one embodiment of the invention, step S1031 is as follows:

[0051] arterial stiffness index=A×W;

[0052] where W denotes the first coefficient.

[0053] In one embodiment, step S103 includes:

[0054] Step S1032, where the arterial stiffness index is obtained based on the difference between the predetermined pressure value and the peak value of the pressure characteristic curve, the length of time corresponding to the predetermined pressure value, and the second coefficient. The second coefficient is a constant related to blood pressure.

[0055] In one embodiment, step S1032 is as follows:

[0056] arterial stiffness index = K1 × L / H;

[0057] where K1 denotes the second factor; L denotes the duration of the period of time corresponding to a predetermined pressure value; and H denotes the difference between the predetermined pressure value and the peak value of the pressure characteristic curve.

[0058] In one embodiment of the invention, step S103 includes:

[0059] Step S1033, where the arterial stiffness index is obtained from the duration of the first time period corresponding to the first curve segment in the pressure characteristic curve, the duration of the second time period corresponding to the second curve segment, and the third coefficient. The first curve segment is the curve segment between the wave crest of the pressure characteristic curve and the first point at the predetermined pressure value, and the second curve segment is the curve segment between the wave crest of the pressure characteristic curve and the second point at the predetermined pressure value.

[0060] In a particular application, the third coefficient is a constant related to blood pressure, and the second coefficient and the third coefficient may be the same.

[0061] In one embodiment of the invention, step S1033 is as follows:

[0062] arterial stiffness index=K2×M/N;

[0063] where K2 denotes the third coefficient, M denotes the duration of the second period of time, and N denotes the duration of the first period of time.

[0064] In one embodiment, step S103 includes:

[0065] Step S1034, where the arterial stiffness index is obtained from the fourth coefficient and the radius of the circle or the length of the long axis of the ellipse fit into a predetermined graph. The predetermined graph is a graph consisting of a line connecting the first point and the second point at a predetermined pressure value on the pressure characteristic curve and a curve segment corresponding to the predetermined pressure value.

[0066] In a specific application, the fourth coefficient is a constant related to blood pressure.

[0067] In one embodiment of the invention, step S1034 is as follows:

[0068] arterial stiffness index = K3 × R;

[0069] where K3 denotes the fourth coefficient, and R denotes the radius of a circle inscribed in a predetermined graph, or the length of the long axis of an ellipse inscribed in this graph.

[0070] In one embodiment, step S103 includes:

[0071] Step S1035, where the arterial stiffness index is obtained from the fifth coefficient and the duration of the time period corresponding to the predetermined pressure value.

[0072] In a specific application, the fifth coefficient is related to the ratio of the arterial stiffness index and the predetermined pressure value. A plurality of ratios of the arterial stiffness index and a predetermined pressure value are obtained in advance by a plurality of actual measurement operations, and a fifth coefficient is obtained by taking a median value, a modal value, or an average value of the plurality of ratios.

[0073] In one embodiment of the invention, step S1035 is as follows:

[0074] arterial stiffness index = K4 × L;

[0075] where K4 denotes the fifth coefficient, and L denotes the duration of the period of time corresponding to a predetermined pressure value.

[0076] In a particular application, the arterial stiffness index unit obtained using each of the above expressions and the standard for measuring the degree of arteriosclerosis do not match. For example, for an arterial stiffness index calculated according to any expression, the median value, modal value, or mean of a plurality of arterial stiffness indices obtained during the calculation of arterial stiffness indices of a large number of patients with normal vascular stiffness, using the expression should be taken as standard meaning. If the arterial stiffness index is clearly greater than the standard value, this means that the degree of arteriosclerosis is large; if the arterial stiffness index is clearly less than the standard value, this indicates that the degree of arteriosclerosis is low; and if the arterial stiffness index is close to or equal to the standard value, this means that the degree of arteriosclerosis is normal.

[0077] In one embodiment of the invention, the method includes the following step, performed after step S101:

[0078] Step S201, where a plurality of arterial vibration amplitude curves are obtained for the time-varying arterial vibration amplitude of the patient based on the pressure value;

[0079] step 202, which obtains the index of arterial stiffness based on the sixth coefficient and the maximum peak value of the arterial vibration amplitude and the minimum peak value of the arterial vibration amplitude in the set of curves of the arterial vibration amplitude.

[0080] In a particular application, the amplitude of the patient's arterial vibration is directly proportional to the pressure value of the pressure sensor; and the patient's arterial vibration amplitude can be obtained by determining the pressure value and performing data conversion. Thus, arterial vibration amplitude curves are obtained, where the amplitude of the patient's arterial vibration changes over time. Because the artery vibrates periodically, the amplitude of the artery's oscillations also changes periodically. Therefore, a plurality of arterial vibration amplitude curves can be obtained within a plurality of time periods.

[0081] In one embodiment of the invention, step S202 is as follows:

[0082] arterial stiffness index = K5 × Hi / Li;

[0083] where K5 denotes the sixth coefficient, Hi denotes the maximum peak value of the arterial vibration amplitude in the arterial vibration amplitude curves, Li denotes the minimum peak value of the arterial vibration amplitude in the arterial vibration amplitude curves, the range of i is [1, n], and i and n are integers.

[0084] In a specific application, the sixth coefficient is a constant related to blood pressure, n can be any integer greater than 1, which must be set according to actual requirements. The larger the value of n, the more accurate the arterial stiffness index. In the case of n = 5 arterial stiffness index = K5 × (H1 + H2 + H3 + H4 + H5) / (L1 + L2 + L3 + L4 + L5). Thus, the arterial stiffness index is obtained by multiplying by a sixth factor the ratio of the sum of the maximum peak values to the minimum peak values of five arterial amplitude curves from a plurality of arterial vibration amplitude curves.

[0085] In one embodiment of the invention, the method includes performing after step S102

[0086] obtaining a temperature value from a temperature sensor, a humidity value from a humidity sensor, an air pressure value from a barometer, and body information and unhealthy living habit information input by a user through a human-computer interface device; and adjusting the pressure characteristic curve according to the temperature value, the humidity value, the air pressure value, body information, and unhealthy life habit information.

[0087] In a specific application, body information includes blood pressure values, gender, age, height, body weight, past medical history, and other patient information. Information on unhealthy living habits includes information on biochemical habits such as smoking, drinking, and staying up late. Various pressure characteristic curves obtained during the measurement of arterial stiffness indices in different patients are purposefully adjusted according to the body information and information about the unhealthy life habits of different patients. Correction schemes for different patients are set in advance based on a large amount of actually measured data.

[0088] In one embodiment of the invention, step S101 includes:

[0089] Step S1011, in which, in the process of pressurizing the shoulder cuff, the range of motion of the patient is determined using the motion detection device, and the wearing position of the shoulder cuff is determined using the shoulder cuff position detection device.

[0090] In step S1012, if the movement range is less than or equal to the predetermined movement range and the wearing position is correct, a pressure value is obtained from the pressure sensor.

[0091] In step S1013, if the range of motion exceeds the predetermined range of motion and the wearing position is incorrect, the pressure value is removed and the human-computer interaction device sends an error message.

[0092] In a particular application, the wearing position of the shoulder cuff and the patient's range of motion directly affect the accuracy of the arterial stiffness index measurement result. When the patient wears the shoulder cuff incorrectly or has a large range of motion, the pressure value obtained by the pressure sensor is inaccurate and cannot be used to obtain an accurate arterial stiffness index, so the pressure value must be deleted and a message sent indicating that the patient's shoulder cuff wearing position is incorrect or movement is wrong. Theoretically, the patient should wear a cuff on the upper arm and keep the body in a static state with the most smooth breathing.

[0093] In step S104, blood pressure and pulse rate values are obtained from the pressure value, the blood pressure values including the highest blood pressure value (systolic blood pressure) and the lowest blood pressure value (diastolic blood pressure).

[0094] In a specific application, blood pressure and pulse rate values may be obtained by performing a pressure value conversion procedure. The pulse pressure value and the patient's cardiac function index can also be obtained according to the pressure value.

[0095] In step S105, at most two of the blood pressure values are displayed using the human-computer interface device, and the pulse rate and arterial stiffness index are displayed.

[0096] In a particular application, a human-computer interface device is used to display an arterial stiffness index, and can also selectively display blood pressure values and/or display a pulse rate according to actual requirements. As shown in FIG. 2, the arterial stiffness index, the highest blood pressure value, the lowest blood pressure value, and the pulse rate are shown as an example, which are digitally displayed at the same time.

[0097] In one embodiment of the invention, the method for determining arterial stiffness further includes the following steps:

[0098] determining whether the arterial stiffness index exceeds a predetermined arterial stiffness index threshold; if the arterial stiffness index is greater than a predetermined arterial stiffness index threshold, a message is sent by the human-computer interface device that the arterial stiffness index exceeds the standard;

or determining whether the highest blood pressure value is greater than a predetermined upper blood pressure limit value, and determining whether the lowest blood pressure value is less than a predetermined lower blood pressure limit value; if the highest blood pressure value is greater than the predetermined upper limit value of blood pressure, or the lowest value of blood pressure is less than the predetermined lower limit value of blood pressure, a message is sent by the human-computer interface device that the blood pressure value is out of range. standard;

or determining whether the pulse rate is within a predetermined pulse rate range; and if the heart rate is out of the predetermined heart rate range, a message is sent by the human-computer interface device that the heart rate is out of the standard range.

[0099] In a particular application, the arterial stiffness index, blood pressure values, and pulse rate are in the normal range, indicating that the patient is healthy. If a certain indicator is outside the normal range, it means that the patient's health condition is abnormal, and thus appropriate prompts must be sent to warn the patient. A specific prompting mode may be to send a prompt via a pop-up window, a warning sign, or a voice prompt. When the prompt mode is to display a warning sign, the warning sign may be displayed in the display area where the corresponding parameter is outside the normal range.

[00100] FIG. 3 shows, by way of example, a warning sign displayed in the arterial stiffness index display area when the arterial stiffness index is greater than a predetermined arterial stiffness index threshold.

[00101] In one embodiment of the invention, the method for determining arterial stiffness further includes the following: the degree of arteriosclerosis of the patient is determined in accordance with the index of arterial stiffness; the degree of arteriosclerosis is displayed by a human-computer interface device; the degree of hypertension in a patient is determined by the values of blood pressure; and the degree of hypertension is displayed by the human-computer interface device.

[00102] In a particular application, different degrees of arteriosclerosis and/or different degrees of hypertension are distinguished and displayed in one or more symbol, graph, table, and color forms.

[00103] FIG. 4 shows, by way of example, that different grades of arteriosclerosis are distinguished and displayed simultaneously with symbols, graphs, and different colors. The arteriosclerosis grade range includes five grades, which indicate a gradual change from normal to severe. An inverted triangle warning sign is displayed in the third degree if the arterial stiffness index is in the third degree.

[00104] In one embodiment of the invention, the method for determining arterial stiffness further includes: displaying the blood pressure value and the degree of hypertension in the form of a two-dimensional coordinate graph through a human-computer interface device. In a particular application, a 2D plot may include one or more display elements such as symbols, graphs, sheets, and different colors to distinguish and display different blood pressure values and different degrees of hypertension.

[00105] FIG. 5 shows, as an example, a graph in two-dimensional coordinates, in which different degrees of hypertension are distinguished and displayed in different colors. The horizontal coordinate indicates the lowest blood pressure value, and the vertical coordinate indicates the highest blood pressure value. A point on the graph in 2D coordinates indicates the coordinate position of the blood pressure value. The magnitude of manifestation of hypertension includes six degrees, which indicate a gradual change from normal to severe. In the fifth degree, an inverted triangle warning sign is displayed if the blood pressure value is in the fifth degree.

[00106] In one embodiment of the invention, a method for determining arterial stiffness further includes:

[00107] displaying the degree of arteriosclerosis and the degree of hypertension as a two-dimensional coordinate graph by means of a human-computer interface device. In a particular application, a 2D plot can also be used to distinguish and display different degrees of arteriosclerosis and different degrees of hypertension.

[00108] FIG. 6 is an example of a graph in two-dimensional coordinates, the horizontal coordinate of which indicates the degree of arteriosclerosis, and the vertical coordinate indicates the degree of hypertension. The point on the graph in 2D coordinates falls within the region representing severe hypertension and normal arterial stiffness.

[00109] In one embodiment of the invention, step S105 includes:

[00110] Displaying at most two data of arteriosclerosis grade and hypertension grade, and displaying arterial stiffness index, blood pressure values, and pulse rate as a multivariate trend graph by a human-computer interface device.

[00111] In a specific application, a plurality of parameters, consisting of the degree of arteriosclerosis, the degree of hypertension, arterial stiffness index, blood pressure values and pulse rate, can be simultaneously displayed using a multivariate trend graph. In a particular application, a multivariate trend chart may include one or more display elements such as symbols, graphs, sheets, and different colors.

[00112] FIG. 7 is an example of a five-dimensional trend graph used to simultaneously display arteriosclerosis grade, hypertension grade, arterial stiffness index, blood pressure values, and pulse rate. Each parameter includes three degrees from normal to severe. On a 5D trend chart, these three degrees are differentiated and displayed as circles or circles of different colors. The degree of arteriosclerosis, the degree of hypertension, arterial stiffness index, blood pressure values and the patient's pulse rate are connected by straight lines in the shape of a pentagon. If the parameter is closer to the central area of the five-dimensional trend plot, this means that the severity is lower or the numerical value is lower; on the contrary, if the parameter is closer to the edge area of the five-dimensional trend plot, this means that the severity is higher or the numerical value is larger.

[00113] In one embodiment, the method for determining arterial stiffness further includes displaying at most four values of blood pressure, pulse rate, arteriosclerosis grade, and hypertension grade, and displaying arterial stiffness index as a dial indicator by means of a human-to-human interface device. computer.

[00114] In a particular application, the dial indicator may be displayed in the form of an arcuate or circular plate. The dial indicator may include one or more display elements such as symbols, graphs, and different colors for distinguishing and displaying various values of blood pressure, pulse rate, degree of arteriosclerosis, degree of hypertension, arterial stiffness indices, and the like.

[00115] FIG. 8 shows as an example a dial indicator used to simultaneously display the degree of arteriosclerosis and arterial stiffness index. The arteriosclerosis scale includes 5 strokes and 6 ranges from normal to severe; the dial indicator is displayed as an arcuate plate; a pointer on the plate is used to indicate the scale corresponding to the numerical value of the arterial stiffness index, and the scale or range of the scale corresponding to the arterial stiffness value. If the arterial stiffness value and the patient's arterial stiffness index are greater, the arrow is closer to the right side; on the contrary, if the degree of arteriosclerosis and the patient's arterial stiffness index are lower, the pointer is closer to the left side.

[00116] In one embodiment of the invention, a method for determining arterial stiffness further includes: obtaining the current time; displaying the current time by means of a human-computer interaction device; analysis of the patient's vascular age based on the index of arterial stiffness; displaying vascular age through a human-computer interface device; obtaining a curve or histogram of at least one of the arterial stiffness index, blood pressure value, pulse rate, and vascular age that changes over time; wherein the curve or histogram is displayed as a graph in two-dimensional coordinates by a human-computer interface device.

[00117] In a specific application, the current time can also be displayed, and the vascular age of the patient is obtained by analysis in accordance with the arterial stiffness index. In addition, changes over time in arterial stiffness index, blood pressure values, pulse rate or vascular age can be displayed in the form of a curve or bar graph in chronological order. When a waveform or bar graph is displayed as a 2D graph, the horizontal coordinate indicates time, and the vertical coordinate indicates arterial stiffness index, blood pressure value, pulse rate, or vascular age.

[00118] FIG. 9 shows arterial stiffness index, blood pressure value, pulse rate, vascular age, and time as an example, which are simultaneously displayed in numerical form.

[00119] In one embodiment of the invention, the method for determining arterial stiffness further includes the following: receiving a display mode switching instruction entered by a user through a human-computer interface device; wherein the display mode of the human-computer interaction device is switched in accordance with the display mode switching instruction.

[00120] In a specific application, a user can input a display mode switching command by a human-computer interaction device according to actual requirements to display all parameters in various display modes. Specific display modes include, but are not limited to, the display modes in the embodiments corresponding to FIGS. 10-17.

[00121] In one embodiment of the invention, the method for determining arterial stiffness further includes analyzing the likelihood of a patient having a cardiovascular disease in accordance with the arterial stiffness index, blood pressure values, and pulse rate, generating an analysis result, and displaying the analysis result through a human interaction device and computer.

[00122] In a specific application, the arterial stiffness determination device specifically compares the measured arterial stiffness index, blood pressure values, and pulse rate of the patient with threshold values corresponding to all parameters. If the parameters are greater than the threshold values, this indicates the likelihood of the presence of the corresponding disease; if on the contrary, it is indicated that there is no probability of the presence of the disease. A cardiovascular disease analysis standard can be preset and stored, and analysis is performed based on this analysis standard. The analysis result can be displayed in various forms such as symbols, graphs and tables, and a voice prompt can also be available.

[00123] In one embodiment of the invention, the method for determining arterial stiffness further includes sending the arterial stiffness index, blood pressure values, pulse rate, and the analysis result to a cloud server via a communication device, wherein the cloud server is used to send the arterial stiffness index, blood pressure values , pulse rate and the result of the analysis of the patient to the doctor, while the doctor diagnoses the patient's disease, and also creates a result of the diagnosis of the disease and sends it to the cloud server for the patient; and the disease diagnosis result sent by the cloud server is received by the communication device; and the diagnosis result of the disease is displayed by the human-computer interface device.

[00124] By means of an arterial stiffness detection device comprising a shoulder cuff, a pressure sensor, and a human-computer interface device, the present exemplary embodiment obtains the pressure value applied by the artery to the pressure sensor in the process of increasing or decreasing the pressure of the shoulder cuff, obtains a characteristic pressure curve for the value time-varying pressure and obtains an arterial stiffness index according to a characteristic of a curve segment corresponding to a predetermined pressure value on the pressure characteristic curve. Therefore, the procedure is simple, a relatively accurate arterial stiffness index can be obtained, and the accuracy of arterial stiffness can be effectively improved. Blood pressure values and pulse rate are obtained according to the pressure value, and no more than two of the blood pressure values, pulse rate and arterial stiffness index are displayed by a human-computer interface device so that various parameters can be simultaneously measured and displayed, and the present embodiment invention is suitable for wide promotion and use.

[00125] It should be understood that the sequence numbers of all the steps in the above exemplary embodiment do not indicate the order of execution. The order of execution of all steps should be determined by their functions and internal logic and should not constitute any restrictions on the implementation steps of the exemplary embodiments of the present invention.

[00126] Example II

[00127] As shown in FIG. 10, the present embodiment of the invention is the arterial stiffness detection system 1 used to carry out the method steps in Example I. The arterial stiffness detection system 1 is implemented based on the arterial stiffness detection device described in Example I, and may in particular have a software management software. System 1 for determining arterial stiffness comprises:

[00128] the first module 101 data collection, configured to receive the pressure value from the pressure sensor in the process of increasing or decreasing the pressure of the shoulder cuff;

[00129] a second data acquisition module 102, configured to generate a pressure characteristic curve of a pressure value that varies with time;

[00130] a third data acquisition unit 103, configured to obtain an arterial stiffness index according to a characteristic of a curve segment corresponding to a predetermined pressure value on the pressure characteristic curve;

[00131] a fourth data acquisition module 104, configured to obtain blood pressure values and pulse rate according to the pressure value, the blood pressure values including the highest blood pressure value and the lowest blood pressure value; and

[00132] A display unit 105 configured to display at most two of the blood pressure values and display a pulse rate and an arterial stiffness index using a human-computer interface device. In one embodiment of the invention, the arterial stiffness display system further comprises:

[00133] a fifth data acquisition module, configured to obtain, based on the pressure value, a plurality of time-varying patient arterial vibration amplitude curves;

[00134] a sixth data acquisition module configured to obtain an arterial stiffness index from a sixth coefficient, a maximum arterial vibration amplitude peak value, and a minimum arterial vibration amplitude peak value in a plurality of arterial vibration amplitude curves.

[00135] In one embodiment of the invention, the system for determining arterial stiffness further comprises:

[00136] A seventh data acquisition module, configured to receive a temperature value from a temperature sensor, a humidity value from a humidity sensor, an atmospheric pressure value from a barometer, and body information and unhealthy life habit information input by a user through a human-computer interface device ;

[00137] A correction unit configured to correct the pressure characteristic curve according to a temperature value, a humidity value, an air pressure value, body information, and unhealthy living habit information.

[00138] In one embodiment of the invention, the system for determining arterial stiffness further comprises:

[00139] a first evaluation module configured to determine whether the arterial stiffness index exceeds a predetermined arterial stiffness index threshold;

[00140] the first auxiliary module, configured to send a message that the arterial stiffness index exceeds the standard, through the human-computer interface device, if the arterial stiffness index is greater than a predetermined arterial stiffness index threshold;

[00141] a second evaluation module, configured to determine whether the highest blood pressure value is greater than a predetermined upper blood pressure limit value, and whether the lowest blood pressure value is less than a predetermined lower blood pressure limit value;

[00142] a second auxiliary module configured to send a message that the blood pressure value is out of the standard range by the human-computer interface device if the highest blood pressure value exceeds a predetermined upper limit blood pressure value or the lowest blood pressure value is less than the predetermined a given lower limit value of blood pressure;

[00143] a third evaluation module configured to determine if the heart rate is within a predetermined heart rate range;

[00144] A third accessory module configured to send an out-of-standard heart rate message via the human-computer interface if the heart rate is not within a predetermined heart rate range.

[00145] In one embodiment of the invention, the system for determining arterial stiffness further comprises:

[00146] the first determination module, configured to determine the degree of arteriosclerosis of the patient based on the arterial stiffness index, the display module is also configured to display the degree of arteriosclerosis through the human-computer interface device;

[00147] the second determination module, configured to determine the degree of hypertension in the patient based on the blood pressure value, the display module is also configured to display the degree of hypertension through the human-computer interface device.

[00148] In one exemplary embodiment of the invention, the display module is also configured to: display the blood pressure values and the degree of hypertension in the form of a graph in two-dimensional coordinates by means of a human-computer interaction device; displaying the degree of arteriosclerosis and the degree of hypertension in the form of a two-dimensional coordinate graph using a human-computer interface device; displaying no more than two parameters from the degree of arteriosclerosis and the degree of hypertension, as well as the index of arterial stiffness, blood pressure values and pulse rate in the form of a multidimensional trend graph through a human-computer interface device; displaying no more than four values of blood pressure, pulse rate, degree of arteriosclerosis and degree of hypertension, as well as arterial stiffness index in the form of a dial indicator by means of a human-computer interface device.

[00149] In one embodiment of the invention, the system for determining arterial stiffness further comprises:

[00150] an eighth data acquisition module, configured to obtain the current time, the display module is also configured to display the current time through the human-computer interface device; an analysis module configured to analyze the user's vascular age according to an arterial stiffness index, the display module also configured to display the vascular age by the human-computer interface device; and a generation module configured to generate a curve or a histogram of at least one of an arterial stiffness index, a blood pressure value, a pulse rate, and a vascular age that changes over time, and

[00151] The display module is also configured to display a curve or a histogram in the form of a graph in two-dimensional coordinates by a human-computer interface device.

[00152] In one embodiment of the invention, the system for determining arterial stiffness further comprises:

[00153] a ninth data acquisition module, configured to receive a display mode switching instruction entered by a user through a human-computer interaction device;

[00154] A switching module configured to switch the display mode of the human-computer interaction device according to the display mode switching instruction.

[00155] In one embodiment of the invention, the analysis module is also configured to analyze the probability that the patient suffers from cardiovascular disease, in accordance with the arterial stiffness index, blood pressure values and pulse rate, and to generate an analysis result.

[00156] The display module is also used to display the result of the analysis through the human-computer interaction device.

[00157] In one embodiment of the invention, the system for determining arterial stiffness further comprises:

[00158] a communication module configured to send the arterial stiffness index, blood pressure values, pulse rate and analysis result to the cloud server through the communication device, the cloud server is configured to send the arterial stiffness index, blood pressure value, pulse rate and analysis result to the patient and the doctor , diagnosing the patient's disease, and for generating the result of diagnosing the disease and sending it to the cloud server by means of the user.

[00159] The communication module is also configured to receive a disease diagnosis result sent by the cloud server via the communication device.

[00160] The display module is also configured to display the diagnosis result of the disease by the human-computer interface device.

[00161] In a particular application, all of the above modules may be implemented by mutually independent processors, or may be typically integrated into a single processor.

[00162] By means of a device for determining arterial stiffness, comprising a shoulder cuff, a pressure sensor and a human-computer interface device, the pressure value applied by the artery to the pressure sensor in the process of increasing or decreasing the pressure of the shoulder cuff is obtained, a characteristic pressure curve is obtained for the pressure value changing during time, and an arterial stiffness index is obtained according to a characteristic of a curve segment corresponding to a predetermined pressure value on the pressure characteristic curve. Therefore, the procedure is simple, a relatively accurate arterial stiffness index can be obtained, and the accuracy of arterial stiffness can be effectively improved. Blood pressure values and pulse rate are obtained according to the pressure value, and no more than two of the blood pressure values, pulse rate and arterial stiffness index are displayed by a human-computer interface device so that various parameters can be simultaneously measured and displayed, and this embodiment invention is suitable for wide promotion and use.

[00163] Example III

[00164] As shown in FIG. 11, the present embodiment is an arterial stiffness detection device 2, comprising: a control unit 201, an exhaust valve 202, a pump 203, a shoulder cuff 204, a pressure sensor 205, a temperature sensor 206, a humidity sensor 207, a barometer 208, a human interaction device 209 and a computer, a motion detection device 210, a shoulder cuff position detection device 211, and a communication device 200.

[00165] The control unit 201 is in communication with a pump 203, a pressure sensor 205, a temperature sensor 206, a humidity sensor 207, a barometer 208, a human-computer interface device 209, a motion detection device 210, a shoulder cuff position detection device 211, and a communication device 200 ; the exhaust valve 202 is located on the shoulder cuff 204; the cuff 204 is mechanically connected to the pump 203, the exhaust valve 202, the pressure sensor 205, the motion detection device 210, and the cuff position detection device 211, respectively; and the communication device 200 is in communicable communication with the cloud server 3; and the cloud server 3 is in communication with the possibility of exchanging data with the doctor's patient 4.

[00166] The control unit 201 is configured to execute the steps of the method for determining arterial stiffness in Example I.

[00167] As shown in FIG. 12, in one embodiment, the control unit 201 comprises a shoulder cuff pressure control unit 2011 and a data processing unit 2012; the shoulder cuff pressure control unit 2011 is connected to the processing unit 2012 and the pump 203; and the processing unit 2012 is connected to a pressure sensor 205, a temperature sensor 206, a humidity sensor 207, a barometer 208, a human-computer interface device 209, a motion detection device 210, a shoulder cuff position detection device 211, and a communication device 200.

[00168] The shoulder cuff pressure control unit 2011 and the data processing unit 2012 are used to perform the steps of the method for determining arterial stiffness in Example I.

[00169] As shown in FIG. 13, in one embodiment of the invention, both the cuff pressure control unit 2011 and the data processing unit 2012 may be mutually independent processors or may be integrated into the same processor. The arterial stiffness determination device 2 further comprises a memory 212 and a machine readable instruction 2121 that is stored in the memory 212 and can be executed by a processor. The processor executes a machine readable instruction to implement the method steps in Example I or the functions of all modules in Example II.

[00170] The arterial stiffness determination device 2 may be an electronic sphygmomanometer. Arterial stiffness determination device 2 may include, but is not limited to, a processor and memory 212. Those skilled in the art will appreciate that FIG. 10 is merely an illustration of the arterial stiffness detection device 2 and is not a limitation of the arterial stiffness detection device 2.

[00171] The memory 212 may be an internal storage unit of the arterial stiffness determination device 2. The memory 212 may also be an external storage device of the arterial stiffness determination device 2, such as a plug-in hard drive provided in the arterial stiffness determination device 2. In addition, the memory 212 may also include both an internal storage unit and an external storage unit of the arterial stiffness determination device 2. The memory 212 is configured to store a computer readable instruction and other readable instructions and data required by the arterial stiffness determination device 2. Memory 212 may also be used to temporarily store data that has been or is to be output.

[00172] Specialists in the art can clearly understand that for convenience and brevity of the description, only the division of the above functional blocks and modules is used for illustration. In addition, the specific names of all functional blocks and modules are used only for the convenience of distinguishing each other and are not used to limit the protection scope of the present invention. For a particular workflow of the blocks and modules of the system described above, reference may be made to the corresponding process in the above exemplary embodiment of the method, the description of which is not repeated here.

[00173] Those skilled in the art can understand that the blocks and steps of the algorithms of all examples described in conjunction with the exemplary embodiments disclosed herein may be implemented by electronic hardware or a combination of computer software and electronic hardware. Whether these functions are performed by hardware or software depends on the particular application and design constraints of the technical solution. Specialists may use different methods for each particular application to implement the described functions, but such an implementation should not be considered as beyond the scope of the present invention.

[00174] In the embodiments of the present invention, it should be understood that the described device/terminal device and method can be implemented in other ways. Blocks described as separate components may or may not be physically separated, and components shown as blocks may or may not be physical blocks, i.e. they may be located in the same location or may be distributed across multiple network blocks. Some or all of the blocks may be selected according to actual needs to achieve the objectives of the solutions of the exemplary embodiments of the invention.

[00175] In addition, all functional blocks in all embodiments of the present invention may be integrated into one processing unit, or each block may physically exist separately, or two or more blocks may be combined into one block. The above integrated blocks may be implemented in hardware or may be implemented in software functional blocks.

[00176] An integrated module/unit, if implemented in the form of a software functional unit and sold or used as a stand-alone product, may be stored on a computer-readable storage medium. Based on this understanding, the present invention implements all or part of the flows in the above-described embodiments of the invention, and can also be performed by specifying the corresponding hardware through machine-readable instructions. The computer-readable instructions may be stored on a computer-readable storage medium. The machine-readable instruction may implement, when executed by a processor, the steps of the method embodiments described above. Machine readable instructions include machine readable instruction codes, and machine readable instruction codes may be in the form of source codes, object codes, executable files, or some intermediate form. The computer-readable medium may comprise any object or device capable of carrying a computer-readable instruction code, a recording medium, a U-disk, a mobile hard disk, a magnetic disk, an optical disk, a computer memory, a read only memory (ROA), a random memory access (RAA), a signal carrier power, communication signal, software distribution environment, etc. It should be noted that content contained on a computer-readable medium may be added or removed as appropriate, in accordance with the requirements of the law and patent practice in the jurisdiction. For example, in some jurisdictions, in accordance with law and patent practice, computer-readable media does not include electrical information-carrying signals and telecommunications signals.

[00177] The above examples of the invention are used only to illustrate the technical solutions of the present invention and are not intended to limit them. Although the present invention has been described in detail with reference to the above exemplary embodiments, those skilled in the art should understand that they may still change the technical solutions recorded in all of the above exemplary embodiments or replace partial specifications with equivalent ones. These modifications and substitutions do not deviate from the essence of the respective technical solutions from the spirit and scope of the technical solutions of all embodiments of the present disclosure and should fall within the protection scope of the present invention.

Claims (112)

1. A method for determining arterial stiffness, implemented on the basis of a device for determining arterial stiffness, which contains a shoulder cuff, a pressure sensor and a human-computer interface device; method for determining arterial stiffness includes: obtaining a pressure value from the pressure sensor in the process of increasing or decreasing the pressure of the shoulder cuff; generating a pressure characteristic curve for a time-varying pressure value; obtaining an arterial stiffness index according to a characteristic of a curve segment corresponding to a predetermined pressure value on the pressure characteristic curve, wherein the characteristic of the curve segment includes a duration of a time interval corresponding to a predetermined pressure value; deriving blood pressure values and pulse rate from the pressure value, the blood pressure values including the highest blood pressure value and the lowest blood pressure value; and displaying at most two of the blood pressure values and displaying the pulse rate and arterial stiffness index by means of a human-computer interface device, said display including: displaying the values of blood pressure and the degree of hypertension in the form of a graph in two-dimensional coordinates through a device for human-computer interaction; or displaying the degree of atherosclerosis and the degree of hypertension as a graph in two-dimensional coordinates by means of a human-computer interface device; or displaying at most two of arteriosclerosis grade and hypertension grade, and displaying arterial stiffness index, blood pressure values, and pulse rate as a multi-dimensional trend graph by a human-computer interface device; or displaying up to four of blood pressure, pulse rate, arteriosclerosis degree, and hypertension degree, and displaying the arterial stiffness index as a dial indicator by means of a human-computer interface device. 2. The method for determining arterial stiffness according to claim 1, further comprising: determining whether the arterial stiffness index exceeds a predetermined arterial stiffness index threshold; if the arterial stiffness index is greater than a predetermined arterial stiffness index threshold, a message is sent by the human-computer interface device that the arterial stiffness index exceeds the standard; or determining whether the highest blood pressure value is greater than a predetermined upper blood pressure limit value and determining whether the lowest blood pressure value is less than a predetermined lower blood pressure limit value; if the highest blood pressure value is greater than the predetermined upper limit value of blood pressure, or the lowest value of blood pressure is less than the predetermined lower limit value of blood pressure, a message is sent by the human-computer interface device that the blood pressure value is out of range. standard; or determining whether the pulse rate is within a predetermined pulse rate range; and if the heart rate is outside the predetermined heart rate range, a message is sent by the human-computer interface device that the heart rate is outside the standard range. 3. The method for determining arterial stiffness according to claim 1, further comprising: determining the degree of arteriosclerosis of the patient in accordance with the index of arterial stiffness; displaying the degree of arteriosclerosis through a human-computer interface device; determining the degree of hypertension of the patient according to the values of blood pressure; displaying the degree of hypertension through a human-computer interface device. 4. The method for determining arterial stiffness according to claim 3, in which: arterial stiffness index = A x W, where W is the first coefficient, A is a constant, or arterial stiffness index = K1 x L / H, where K1 is the second coefficient; L is the duration of the time interval corresponding to a predetermined pressure value; and H is the difference between the predetermined pressure value and the peak value of the pressure characteristic curve, or Arterial Stiffness Index = K2 x M / N where K2 is the third factor, M is the duration of the second time period and N is the duration of the first time period, the first segment of the curve is the segment of the curve between the wave crest on the pressure characteristic curve and the first point at predetermined pressure value, and the second curve segment is the curve segment between the crest of the wave on the characteristic pressure curve and the second point at the predetermined pressure value, or arterial stiffness index = K3 x R where K3 is the fourth factor and R is the radius of a circle inscribed in a predetermined graph, or the length of the long axis of an ellipse inscribed in this graph, the predetermined graph is a graph consisting of a line connecting a first point and a second point at a predetermined pressure value on the characteristic pressure curve, and a curve segment corresponding to a predetermined pressure value, or arterial stiffness index = K4 x L, where K4 is the fifth factor and L is the duration of the time interval corresponding to a predetermined pressure value, or arterial stiffness index = K5 x Hi / Li, where K5 is the sixth coefficient, Hi is the maximum peak value of the arterial vibration amplitude on the arterial vibration amplitude curves, Li is the minimum peak value of the arterial vibration amplitude on the arterial vibration amplitude curves, the range of i is [ 1, n], and i and n are integers, wherein the first coefficient is a coefficient associated with the duration of the time interval corresponding to a predetermined pressure value, the second, third, fourth and sixth coefficients are constants associated with arterial pressure, the fifth coefficient is associated with the ratio of the arterial stiffness index and a predetermined pressure value . 5. The method for determining arterial stiffness according to claim 1, further comprising: getting the current time; displaying the current time by means of a human-computer interaction device; analysis of the patient's vascular age according to the index of arterial stiffness; displaying vascular age through a human-computer interface device; generating a curve or histogram of at least one of an arterial stiffness index, blood pressure value, pulse rate, and vascular age that varies over time; displaying a curve or histogram as a graph in two-dimensional coordinates by means of a human-computer interface device. 6. The method for determining arterial stiffness according to claim 1, further comprising: receiving a display mode switching instruction inputted by the user through the human-computer interaction device; switching the display mode of the human-computer interaction device according to the display mode switching instruction. 7. The method for determining arterial stiffness according to claim 1, further comprising: analyzing a probability that the patient is suffering from a cardiovascular disease according to the arterial stiffness index, blood pressure values, and pulse rate, and generating an analysis result; displaying the analysis result by means of a human-computer interaction device. 8. The arterial stiffness determination method according to claim 7, wherein the arterial stiffness determination device further comprises a communication device, and the arterial stiffness determination method further comprises: sending the arterial stiffness index, blood pressure values, pulse rate, and analysis results to a cloud server via a communication device, using the cloud server to send the arterial stiffness index, blood pressure values, pulse rate, and patient analysis result to a physician diagnosing the patient's disease, and generating a diagnosis result disease and sending it to the cloud server for the patient; receiving a diagnosis result of the disease sent by the cloud server through the communication device; displaying the result of diagnosing a disease by means of a human-computer interaction device. 9. The arterial stiffness determination method according to claim 1, further comprising adjusting the pressure characteristic curve according to the temperature value, the humidity value, the air pressure value, the body information, and the unhealthy life habit information of the user. 10. The system for determining arterial stiffness, implemented on the basis of the device for determining arterial stiffness, while the device for determining arterial stiffness contains a shoulder cuff, a pressure sensor and a human-computer interface device; system for determining arterial stiffness contains: a first data acquisition module, configured to receive a pressure value from the pressure sensor in the process of increasing or decreasing the pressure of the shoulder cuff; a second data acquisition module, configured to generate a pressure characteristic curve for a time-varying pressure value; a third data acquisition module configured to obtain an arterial stiffness index according to a characteristic of a wave segment corresponding to a predetermined pressure value on the pressure characteristic curve, wherein the characteristic of the wave segment includes a length of time corresponding to a predetermined pressure value; a fourth data acquisition module, configured to obtain blood pressure values and pulse rate according to the pressure value, the blood pressure values comprising the highest blood pressure value and the lowest blood pressure value; and a display module configured to display at most two blood pressure values and display pulse rate and arterial stiffness index by means of a human-computer interface device, said display including: displaying the values of blood pressure and the degree of hypertension in the form of a graph in two-dimensional coordinates through a device for human-computer interaction; or displaying the degree of atherosclerosis and the degree of hypertension as a graph in two-dimensional coordinates by means of a human-computer interface device; or displaying at most two of arteriosclerosis grade and hypertension grade, and displaying arterial stiffness index, blood pressure values, and pulse rate as a multi-dimensional trend graph by a human-computer interface device; or displaying up to four of blood pressure, pulse rate, arteriosclerosis degree, and hypertension degree, and displaying the arterial stiffness index as a dial indicator by means of a human-computer interface device. 11. A device for determining arterial stiffness, containing a control unit, a pump, an exhaust valve, a shoulder cuff, a pressure sensor, a human-computer interaction device and a communication device, wherein the control unit is in communication with the pump, the pressure sensor, the human-computer interface and the communication device, respectively; the exhaust valve is located on the shoulder cuff; the shoulder cuff is mechanically connected to the pump, outlet valve and pressure sensor, respectively; the communication device is in communication with the ability to exchange data with the cloud server; the control unit is configured to perform the following actions: obtaining a pressure value of the pressure sensor in the process of increasing or decreasing the pressure of the shoulder cuff; generating a pressure characteristic curve for a time-varying pressure value; obtaining an arterial stiffness index based on a characteristic of a curve segment corresponding to a predetermined pressure value on the characteristic pressure curve, wherein the characteristic of the curve segment includes a duration of a time interval corresponding to a predetermined pressure value; deriving blood pressure and pulse rate values from the pressure values, the blood pressure values comprising the highest blood pressure value and the lowest blood pressure value; and displaying no more than two values of blood pressure and pulse rate, as well as an arterial stiffness index by means of a human-computer interface device, while said display includes: displaying the values of blood pressure and the degree of hypertension in the form of a graph in two-dimensional coordinates through a device for human-computer interaction; or displaying the degree of atherosclerosis and the degree of hypertension as a graph in two-dimensional coordinates by means of a human-computer interface device; or displaying at most two of arteriosclerosis grade and hypertension grade, and displaying arterial stiffness index, blood pressure values, and pulse rate as a multi-dimensional trend graph by a human-computer interface device; or displaying up to four of blood pressure, pulse rate, arteriosclerosis degree, and hypertension degree, and displaying the arterial stiffness index as a dial indicator by means of a human-computer interface device. 12. The arterial stiffness determination device of claim 11, wherein the control unit is further configured to perform the following actions: determining whether the arterial stiffness index exceeds a predetermined arterial stiffness index threshold; if the arterial stiffness index is greater than a predetermined arterial stiffness index threshold, a message is sent by the human-computer interface device that the arterial stiffness index is greater than the standard; or determining whether the highest blood pressure value is greater than a predetermined upper blood pressure limit value and determining whether the lowest blood pressure value is less than a predetermined lower blood pressure limit value; if the highest blood pressure value is greater than the predetermined upper limit value of blood pressure, or the lowest value of blood pressure is less than the predetermined lower limit value of blood pressure, a message is sent by the human-computer interface device that the blood pressure value is out of range. standard; or determining whether the pulse rate is within a predetermined pulse rate range; and if the heart rate is out of the predetermined heart rate range, a message is sent by the human-computer interface device that the heart rate is out of the standard range. 13. The arterial stiffness determination device of claim 11, wherein the control unit is further configured to perform the following actions: determining the degree of arteriosclerosis of the patient in accordance with the index of arterial stiffness; displaying the degree of arteriosclerosis through a human-computer interface device; determining the degree of hypertension of the patient according to the values of blood pressure; displaying the degree of hypertension through a human-computer interface device. 14. The arterial stiffness determination device of claim 11, wherein the control unit is further configured to perform the following actions: getting the current time; displaying the current time by means of a human-computer interaction device; analysis of the patient's vascular age according to the index of arterial stiffness; displaying vascular age through a human-computer interface device; generating a curve or histogram of at least one of an arterial stiffness index, blood pressure value, pulse rate, and vascular age that varies over time; displaying a curve or histogram as a graph in two-dimensional coordinates by means of a human-computer interface device. 15. The arterial stiffness determination device of claim 11, wherein the control unit is further configured to perform the following actions: receiving a display mode switching instruction inputted by the user through the human-computer interaction device; switching the display mode of the human-computer interaction device according to the display mode switching instruction. 16. The arterial stiffness determination device of claim 11, wherein the control unit is further configured to perform the following actions: analyzing a probability that the patient is suffering from a cardiovascular disease according to the arterial stiffness index, blood pressure values, and pulse rate, and generating an analysis result; displaying the analysis result by means of a human-computer interaction device. 17. The arterial stiffness determination device according to claim 16, further comprising a communication device, in which the control unit is further configured to perform the following actions: sending the arterial stiffness index, blood pressure values, pulse rate, and analysis results to a cloud server via a communication device, using the cloud server to send the arterial stiffness index, blood pressure values, pulse rate, and patient analysis result to a physician diagnosing the patient's disease, and generating a diagnosis result disease and sending it to the cloud server for the patient; receiving a diagnosis result of the disease sent by the cloud server through the communication device; displaying the result of diagnosing a disease by means of a human-computer interaction device. 18. A machine-readable storage medium that stores a machine-readable instruction; A machine-readable instruction, when executed by a processor, performs the following actions: obtaining a pressure value from the pressure sensor in the process of increasing or decreasing the pressure of the shoulder cuff; generating a pressure characteristic curve for a time-varying pressure value; obtaining an arterial stiffness index according to a characteristic of a curve segment corresponding to a predetermined pressure value on the pressure characteristic curve, wherein the characteristic of the curve segment includes a duration of a time interval corresponding to a predetermined pressure value; deriving blood pressure values and pulse rate from the pressure value, the blood pressure values including the highest blood pressure value and the lowest blood pressure value; and displaying at most two of the blood pressure values and displaying the pulse rate and arterial stiffness index by means of a human-computer interface device, said display including: displaying the values of blood pressure and the degree of hypertension in the form of a graph in two-dimensional coordinates through a device for human-computer interaction; or displaying the degree of atherosclerosis and the degree of hypertension as a graph in two-dimensional coordinates by means of a human-computer interface device; or displaying at most two of arteriosclerosis grade and hypertension grade, and displaying arterial stiffness index, blood pressure values, and pulse rate as a multi-dimensional trend graph by a human-computer interface device; or displaying up to four of blood pressure, pulse rate, arteriosclerosis degree, and hypertension degree, and displaying the arterial stiffness index as a dial indicator by means of a human-computer interface device. 19. The computer-readable storage medium of claim 18, wherein the computer-readable instruction, when executed by the processor, further performs the following: determining whether the arterial stiffness index exceeds a predetermined arterial stiffness index threshold; if the arterial stiffness index is greater than a predetermined arterial stiffness index threshold, a message is sent by the human-computer interface device that the arterial stiffness index exceeds the standard; or determining whether the highest blood pressure value is greater than a predetermined upper blood pressure limit value and determining whether the lowest blood pressure value is less than a predetermined lower blood pressure limit value; if the highest blood pressure value is greater than the predetermined upper limit value of blood pressure, or the lowest value of blood pressure is less than the predetermined lower limit value of blood pressure, a message is sent by the human-computer interface device that the blood pressure value is out of range. standard; or determining whether the pulse rate is within a predetermined pulse rate range; and if the heart rate is out of the predetermined heart rate range, a message is sent by the human-computer interface device that the heart rate is out of the standard range. 20. The computer-readable storage medium of claim 18, wherein the computer-readable instruction, when executed by the processor, further performs the following: determining the degree of arteriosclerosis of the patient in accordance with the index of arterial stiffness; displaying the degree of arteriosclerosis through a human-computer interface device; determining the degree of hypertension of the patient according to the values of blood pressure; displaying the degree of hypertension through a human-computer interface device.

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