Method and system for detecting blood sugar of experimental animal

文档序号:1678009 发布日期:2020-01-03 浏览:27次 中文

阅读说明:本技术 一种实验动物血糖检测方法与系统 (Method and system for detecting blood sugar of experimental animal ) 是由 邓娟 王磊 沙洪 于 2018-06-27 设计创作,主要内容包括:本发明公开了一种用于实验动物的血糖检测方法和系统,其特征在于,检测系统包括血糖测量模块、供电模块、控制模块和无线数据通讯模块,供电模块和无线数据通讯模块都分为体内和体外两部分,血糖测量模块包括葡萄糖传感器、三电极检测电路和恒电位等外围电路,供电模块采用基于磁耦合谐振的无线供电方式,主要由电流发生电路、LC匹配发射线圈、LC匹配接收线圈和接收电能调理电路组成,控制模块和无线数据通讯模块都基于低功耗蓝牙系统芯片实现,实验过程中将研制的系统通过一次植入手术植入实验动物腹腔,通过无线数据通讯模块体外端启动植入体内的部分开始工作,定时测量血糖数据并发送至体外无线数据通讯端进行分析,定时通过供电模块体外端启动充电。(The invention discloses a blood sugar detection method and a system for experimental animals, which is characterized in that the detection system comprises a blood sugar measuring module, a power supply module, a control module and a wireless data communication module, wherein the power supply module and the wireless data communication module are divided into an in vivo part and an in vitro part, the blood sugar measuring module comprises a glucose sensor, a three-electrode detection circuit, a constant potential and other peripheral circuits, the power supply module adopts a wireless power supply mode based on magnetic coupling resonance and mainly comprises a current generating circuit, an LC matching transmitting coil, an LC matching receiving coil and a received electric energy conditioning circuit, the control module and the wireless data communication module are realized based on a low-power consumption Bluetooth system chip, the developed system is implanted into the abdominal cavity of the experimental animals through one-time implantation operation in the experimental process, the part implanted into the body is started to work through the external end of the wireless data communication module, and the blood glucose data is measured at regular time and sent to an in-vitro wireless data communication end for analysis, and the charging is started at regular time through the external end of the power supply module.)

1. The utility model provides a blood sugar detecting system for experimental animals, characterized by, the system includes blood sugar measuring module, power module, control module and wireless data follow communication module, power module and wireless data communication module all divide into internal and external two parts, blood sugar measuring module includes peripheral circuits such as glucose sensor, three-electrode detection circuit and constant potential, power module adopts the wireless power supply mode based on magnetic coupling resonance, mainly matches transmitting coil, LC by current generating circuit, LC and matches receiving coil and receive electric energy conditioning circuit and constitute, control module and wireless data communication module all realize based on the bluetooth low energy system chip.

2. The method as claimed in claim 1, wherein the blood sugar test system of the laboratory animal is implanted into the abdominal cavity of the laboratory animal after the laboratory animal is implanted once during the experiment, the implanted part is started to start working by the external end of the wireless data communication module, the blood sugar data is measured and sent to the external wireless data communication terminal, and the charging is started by the external end of the power supply module.

Technical Field

The invention relates to the field of biomedical signal detection, in particular to a method and a system for measuring blood sugar of an experimental animal.

Background

Diabetes is the 3 rd chronic non-infectious disease threatening human health worldwide. The 2010 epidemiological survey results show that the diabetes incidence rate of Chinese adults is up to 11.6%, patients are in a low-age trend, and 50.1% of adults are in the early stage of diabetes. Although the basic mechanisms of diabetes mellitus were confirmed in the early 20 th century, the specific pathogenesis and pathogenic factors have not been clarified yet. Therefore, the physiological pathology and the development of new drugs of diabetes are always important scientific research directions. The research is mostly carried out on the basis of experimental animals, and the accuracy and the reliability of the blood sugar detection of the experimental animals are very important.

At present, the blood sugar data of experimental rats are mainly measured by taking blood manually and then measuring the blood sugar in vitro. When the experiment is carried out in the mode, the rat needs to be subjected to blood sampling operation for many times, and the common blood sampling operation of the rat is to perform extrusion type blood sampling after an incision is made at the tail part of the rat. This repetitive injury can cause stress in the rat, affecting the accuracy of blood glucose measurements. In order to obtain enough experimental data, the semi-automatic mode needs a plurality of experimental operations of the experimenter, and the labor intensity of the experimenter is increased. In addition, the experimental period of a common rat model is 90-300 days, but the skin damage caused by repeated blood taking is difficult to heal, which directly limits the application of the technology to long-term blood sugar monitoring of experimental animals. Generally, only about 10 measurement operations can be performed depending on the interval between blood sampling operations. The time interval of the blood sampling measurement operation is long, generally about one day to one week, and real-time blood glucose change data after administration is difficult to obtain. The intermittent point type measurement has certain data defects compared with the continuous blood sugar detection technology, and intensive blood sugar information in unit time cannot be obtained, so that further experimental research is influenced.

The blood glucose detection of experimental animals requires the emergence of a more convenient and accurate continuous blood glucose measurement technique. The continuous blood sugar detection technology can be classified into non-invasive and invasive technologies in terms of invasion of an organism. In the noninvasive detection based on optical or microwave, laser light, microwave, or the like is applied to subcutaneous tissues of a living body, and the glucose concentration in the tissues is estimated by utilizing the characteristics of glucose molecules such as light transmission and light reflection, which are near-infrared light absorption characteristics. Because the blood sugar concentration in a living body is influenced by various factors and has complex change, the noninvasive and indirect measurement has the problems of background interference, low sensitivity, low signal-to-noise ratio, large error, overlong response time and the like.

The invasive technique of blood glucose aims at directly detecting the glucose concentration in interstitial fluid, and since the glucose concentrations in interstitial fluid and blood have a high correlation, the blood glucose concentration can be obtained by conversion. The development has been rapid in recent years because it can overcome the drawbacks of non-invasive detection and is easier to implement. The technical measurement mode mainly comprises the following steps: subcutaneous and total implantation by micro-sensors in a minimally invasive manner. The semi-implantation method has some possible defects in clinical application, for example, the contact part of the lead and skin tissues may have inflammatory reaction, the portable external part may affect the continuity of normal life activities, for experimental animals, the activities of the experimental animals cannot be guaranteed within the range that the system measurement is not affected due to the uncontrollable activities, and therefore, the semi-implantation method is only suitable for anesthetizing the animals. The full-implantation type method is a blood sugar measuring technology which can implant a peripheral measuring device into a body together on the basis of a minimally invasive sensor and can detect the blood sugar only after one-time implantation operation. Although invasive detection is adopted, the invasive operation is not required for each measurement, and the blood glucose data can be automatically and continuously measured by the in-vivo system after the target organism naturally recovers through one implantation operation.

Implantable continuous blood glucose monitoring systems measure and record blood glucose concentrations in vivo continuously by glucose sensors implanted inside tissues or inside blood vessels. The advantages are that: the electronic system implanted in the organism can be used for detecting the blood sugar information in the organism, and the continuous dynamic measurement under the natural state of low invasion is realized. Compared with the traditional detection means, the method mainly has the following advantages: after the in vivo stress reaction of the rat after one implantation operation, the natural blood sugar data of the rat in normal life activities can be measured, and the stress blood sugar change caused by blood sampling can not be generated; and secondly, after the implant is implanted into the abdominal cavity of a rat through an operation, continuous blood sugar detection can be carried out, and blood sugar information blind spots caused between two blood sampling measurements and when no measurement is carried out at night are avoided. Meanwhile, the continuous blood sugar information curve is beneficial to scientific research personnel to carry out trend prediction and rule summarization on blood sugar change; thirdly, the implantable blood glucose device can perform timing detection in vivo, so that the attention of experimenters to the blood glucose measuring process and blood sampling measurement at each time are avoided, and real-time blood glucose change data after administration can be provided for pharmaceutical research. Comprehensive analysis shows that the implanted blood sugar measurement technology provides a means for accurately and reliably measuring the blood sugar of an experimental animal in vivo in the research of pathogenesis or pharmacodynamics of diabetes.

An implantable blood glucose detection system generally includes an implant part and an external part, wherein the internal part is used for detecting and transmitting blood glucose information, and the external part is used for receiving and processing data. Because the target is implanted in a rat with small volume, the volume and the weight of the implant are greatly limited, the volume is small, the weight does not exceed one twentieth of the weight of the rat generally, and the normal activity of the rat cannot be influenced. The working electrode of the implant acquires a signal corresponding to the blood glucose concentration through the sensor, and the signal is converted into a digital signal after amplification and filtering and is sent to the outside of the body through wireless communication. The external hardware design depends on the hardware design requirements of the implant, such as power consumption, power supply mode, data transmission mode and the like of the implant. In order to ensure the normal and stable operation of the system, the design of power supply of the implant is very critical.

Disclosure of Invention

The technical problem to be solved by the invention is to overcome the defects in the prior art aiming at the purpose of collecting the blood sugar information of the experimental animal, and to prepare a full-implanted wireless continuous dynamic blood sugar detection system for monitoring the blood sugar when the experimental animal moves freely, and implant the system into the abdominal cavity of the experimental animal, thereby accurately and reliably obtaining the blood sugar information and the variation trend thereof.

The invention provides a core component of a full-implanted wireless continuous dynamic experimental animal blood sugar detection system, which is an implant part, and the external part realizes the functions of blood sugar data receiving and wireless power supply transmitting. The detection system mainly comprises a blood sugar measuring module, a wireless power supply module and a wireless data communication and control module, and the structural block diagram of the detection system is shown in figure 1. The blood sugar detection circuit technical design part comprises a glucose sensor, a three-electrode detection circuit, a constant potential and other peripheral circuits. A block diagram of a three-electrode blood glucose measurement circuit is shown in fig. 2. The power supply mode adopts a mode of wireless power transmission power supply based on magnetic coupling resonance. The control module and the wireless data communication module are realized based on a low-power Bluetooth system chip.

The heart of the blood glucose detection system is a glucose sensor. The invention uses a three-electrode glucose sensor. Compared with a reference electrode introduced into the two electrodes, the three-electrode sensor is not easy to polarize and has constant potential because the current flowing through the reference electrode is very small and is made of common bio-inert materials such as platinum and the like, so that the sensor keeps relatively consistent electrochemical performance in the whole measuring process, and the measuring result is more accurate and stable. The working electrode and the auxiliary electrode form a current loop for measuring the current. The three-electrode current sensing circuit implementation is shown in fig. 3.

The invention adopts a wireless power supply mode based on magnetic coupling resonance to supply power for the blood sugar dynamic monitoring circuit, and solves the problem of power supply of an implant. The power supply module comprises an internal part and an external part, and the system block diagram is shown in fig. 4. The device mainly comprises a current generating circuit, an LC matching transmitting coil, an LC matching receiving coil and a received electric energy conditioning circuit. The current generating circuit generates high-frequency alternating current, the high-frequency alternating current enables the LC transmitting coil to generate resonance, the matching receiving coil with the same resonance frequency induces the magnetic field change in the space to generate corresponding alternating current, and the alternating current passes through the conditioning circuit, and after a series of rectification and voltage stabilization processing, constant voltage power supply is provided for the implant. The current generating circuit is the core of the whole wireless power supply part, and the invention adopts a current-adjustable high-frequency sine alternating current source, and the block diagram of the current-adjustable high-frequency sine alternating current source is shown in figure 5. The receiving part comprises a receiving coil loop and an electric energy conditioning circuit, the electric energy conditioning circuit comprises a filtering and voltage stabilizing circuit, and the constant voltage obtained by the voltage stabilizing circuit supplies power for the blood sugar measurement and the wireless communication module. The voltage required by the blood glucose measuring module comprises 3V operational amplifier voltage; the CC2540 wireless communication power supply voltage range is 1.8-3.6V, and the power supply voltage is 3V as that of the blood sugar measuring module for simplifying the internal circuit part. The receiving coil loop adopts a parallel resonant circuit, and the receiving loop can be approximately equivalent to a current source, so that the output current is not influenced by the resistance value of the load, and the output power of the load end is greatly improved. The receive coil power conditioning circuit is shown in fig. 6.

The invention adopts 4.0-BLE technology to realize the wireless transmission of blood glucose data. The performance requirements of the wireless communication module mainly include data transmission rate, data transmission reliability, communication distance, transmission power consumption and the like. According to the sampling rate of acquiring 12-bit sampling data every minute, data transmission is required every 15 minutes, and the minimum rate requirement of wireless communication is 102.4 bps. The Bluetooth 4.0 technology with low power consumption has low communication power consumption, 68mW/Mbps power efficiency and good convenience on the basis of meeting the requirements of distance and data transmission rate.

The circuit of the invention is integrated on two discrete circuit boards, namely a blood sugar detection board and a wireless data communication board. The blood glucose detection board is mainly provided with a three-electrode detection circuit and a glucose sensor interface, and the wireless data communication board is provided with a minimum circuit and a rectification and voltage stabilization module circuit which take a low-power-consumption Bluetooth 4.0 chip as a core. The two circuit boards are connected through flying wires, have similar sizes and are convenient to implant. The wireless communication circuit board is connected with the wireless receiving coil to form an implant system. Because the implant is provided with a wireless power supply circuit and the metal material can generate heat in a magnetic field, the common titanium alloy is not selected for packaging on the packaging material, but the medical epoxy resin material is adopted for packaging. The circuits are all included in epoxy resin, and only the glucose sensor is exposed to be in direct contact with the environment in the animal body. The packaging material has good biocompatibility and sealing property, and is suitable for implantation environment.

Drawings

FIG. 1 is a block diagram of a blood sugar test system for experimental animals.

1 is the implant part, 2 is the boundary skin between the in vivo and in vitro environment, and 3 is the extracorporeal part of the system.

FIG. 2 is a block diagram of a three-electrode blood glucose measurement circuit.

4 is a reference electrode, 5 is an auxiliary electrode, and 6 is a working electrode.

Fig. 3 is a three-electrode current detection circuit diagram.

Fig. 4 is a block diagram of a wireless power supply module based on magnetic coupling resonance.

Fig. 5 is a block diagram of a current-regulated high-frequency sinusoidal ac current source.

Fig. 6 is a diagram of a receive coil power conditioning circuit.

Reference numeral 7 denotes a receiving capacitor, and 8 denotes a receiving coil.

Detailed Description

The invention is further described below with reference to the accompanying drawings.

The invention relates to a full-implanted wireless continuous dynamic experimental animal blood sugar detection system, which comprises an implant body and an external receiving end, wherein data transmission between the implant body and the external receiving end adopts a wireless mode. The blood glucose meter mainly comprises a blood glucose measuring module, a power supply module, a control module and a wireless data communication module, and the structural block diagram of the blood glucose meter is shown in figure 1.

The blood sugar measuring module comprises a glucose sensor and peripheral circuits such as a constant potential. The SOF-SENSOR glucose SENSOR available from American Meindon force corporation is a three-electrode electrochemical SENSOR with glucose oxidase attached, and the working potential is about 0.7V. The three electrodes include an auxiliary electrode, a working electrode, and a reference electrode. The reference electrode has a constant potential, for example, the potentials of the auxiliary electrode and the working electrode are changed in the measurement process, the working potential can be more accurately clamped through the reference electrode, the potential change between the auxiliary electrode and the working electrode corresponds to the blood glucose concentration, and the circuit structure block diagram is shown in fig. 2. The constant potential generating circuit is used for providing working potential and can be obtained by voltage division of a precision resistor. The current detection circuit selects the operational amplifier 0PA4330 of the TI, the operational amplifier has small bias current, the noise voltage formed by the bias current on the feedback resistor can be effectively reduced, and the interference on the detection of the working current is reduced. A three-electrode current sensing circuit diagram is shown in fig. 3.

The power supply module of the system comprises an internal part and an external part, and the system block diagram is shown in figure 4 and mainly comprises a current generating circuit, an LC matching transmitting coil, an LC matching receiving coil and a received electric energy conditioning circuit. The current generating circuit generates high-frequency alternating current, the high-frequency alternating current enables the LC transmitting coil to generate resonance, the matching receiving coil with the same resonance frequency induces the magnetic field change in the space to generate corresponding alternating current, and the alternating current passes through the conditioning circuit, and after a series of rectification and voltage stabilization processing, constant voltage power supply is provided for the implant. The current generating circuit is the core of the whole wireless power supply part, and adopts a current-adjustable high-frequency sine alternating current source, and the block diagram is shown in fig. 5. The adjustable high-frequency current generating device is characterized in that 220V commercial power is converted into a direct current electric signal through a rectifying and filtering circuit, a direct current chopper circuit is connected with a power adjusting circuit, and the direct current voltage at the input end of a full-bridge inverter driving circuit is controlled through the power adjusting circuit to achieve the set transmitting power. The direct current voltage is converted into high-frequency square wave voltage through the full-bridge inverter circuit to be used as the input of the LC oscillator circuit, and the resonance compensation capacitor and the transmitting coil inductor form a transmitting end resonance loop. The device comprises a rectifying filter circuit, a direct current chopper circuit, a power regulating circuit, an overcurrent and overheat detection circuit, a full-bridge inverter circuit, a frequency tracking inverter control circuit and a serial RLC (radio link control) oscillator circuit. The transmitting loop is a load circuit of the full-bridge inverter driving circuit, namely an RLC resonant circuit, and comprises a matching capacitor and a transmitting coil. The receiving part comprises a receiving coil loop and a power conditioning circuit, and the circuit diagram is shown in fig. 6. The electric energy conditioning circuit comprises a filtering and voltage stabilizing circuit, and the constant voltage obtained by the voltage stabilizing circuit supplies power for the blood sugar measurement and wireless communication module. The receiving coil loop adopts a parallel resonant circuit, the current flowing into the capacitor at the moment is offset with the power component of the current in the receiving coil, the receiving loop can be approximately equivalent to a current source, so that the output current is not influenced by the resistance value of the load, and the output power of the load end can be greatly improved.

The implanted body in the body transmits the blood sugar information to the receiving end in the body through wireless communication. The performance requirements of the wireless communication module mainly include a data transmission rate, data transmission reliability, a communication distance, transmission power consumption and the like, wherein the sampling rate of 12-bit sampling data is acquired every minute, data transmission is required once every 15 minutes, the lowest rate requirement of wireless communication is 102.4bps, and the above technologies can meet the requirements, so that the power consumption and the convenience of communication become main limiting factors. The 4.0-BLE is selected as the blood glucose data wireless transmission scheme of the research, and a CC2540 communication module can be selected on a specific chip. The circuit structure selects the minimum system of the CC2540 communication module so as to achieve the purpose of reducing the volume on the basis of meeting the required functions. The CC2540 module peripheral clock part circuit selects 32MHz and 32.768kHz crystal oscillators, wherein the 32.768kHz external crystal oscillator is enabled when the system is in a sleep state. A matching circuit is formed by a plurality of resistance-capacitance networks and is used as a radio frequency front end; a chip Compact read Xtend ceramic antenna from TI corporation may be selected.

In the aspect of packaging the implant, the circuits are integrated on two separate circuit boards, namely a blood glucose detection board and a wireless data communication board. The blood glucose detection board is mainly provided with a three-electrode detection circuit and a glucose sensor interface, and the wireless data communication board is provided with a minimum circuit and a rectification and voltage stabilization module circuit which take a low-power-consumption Bluetooth 4.0 chip as a core. The two circuit boards are connected through flying wires, have similar sizes and are convenient to implant. The wireless communication circuit board is connected with the wireless receiving coil to form an implant system. Because the implant is provided with a wireless power supply circuit and the metal material can generate heat in a magnetic field, the common titanium alloy is not selected for packaging on the packaging material, but the medical epoxy resin material is adopted for packaging. The circuits are all included in epoxy resin, and only the glucose sensor is exposed to be in direct contact with the environment in the animal body. The packaging material has good biocompatibility and sealing property, and is suitable for implantation environment.

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