TWI527562B - Portable diagnostic measuring device - Google Patents

Description

Portable diagnostic measuring device

The invention is a portable diagnostic measuring device capable of recording at least one physiological parameter of a human body in a non-invasive manner.

At present, there is more and more consciousness and willingness in the population. In order to hope to monitor their own health independently, they can continue to clearly understand their own health status in preventing diseases. In recent years, the use of a blood pressure measuring device, a thermometer to measure whether or not a fever, and a so-called body fat meter for measuring the body fat ratio have been frequently used by ordinary people.
Therefore, portable diagnostic measuring devices have tended to be suitable for use and operation at home without limitations in space usage.
For example, the patent of the measuring device related to DE60108673T2 is an example of measuring a certain physiological parameter of the human body. If electrodes are used to monitor body obesity, this method is to place the thumb on the front electrode of the measurement and place the remaining fingers on the measurement device that provides the back electrode of the power supply end.

Conversely, the device of the present invention provides a portable diagnostic measuring device that can record at least one physiological parameter of the human body in a non-invasive manner.
This invention will be completed by its unique patent requirements. The specific content of the preferred patent will be explained by the patent requirements below.
More particularly, a portable diagnostic measuring device can record at least one physiological parameter of the human body in a non-invasive manner. Because the device includes an integrated sensor, physiological parameters can be recorded; an integrated evaluation unit can evaluate the physiological parameters, estimate the calculated parameters, and display the values. The device has a base and a cover at the same time, and the cover is movable to rotate as a closing and closing action with the base. The cover and the base have a surface layer for placing the human finger, and at least one sensor is placed on the surface layer; the finger can be placed in the closed position between the cover and the base, so the physiological parameters The recording action of the physiological parameter is completed at the closed position.
The device of the invention has the advantage that the finger can be fixedly placed between the cover and the base, so that the measurement of the physiological parameters of the human body can be repeated. Because of this, on the surface of the finger, there is a stop sign that guides the finger to confirm that the finger is in the direction when the cover is closed, and also confirms that it is fixed at the test placement position.
When the finger is placed in the so-called recessed area, the finger is thus fixed perpendicular to the extended surface of the recessed area. After this design, it is previously feared that the finger cannot be accurately contacted with the sensor, and thus is solved. On the other hand, due to this design, the finger of the tested person can be measured repeatedly at the same position, so even if the test time is different, the same person can reliably measure his own physiological parameters. Record physiological parameters at different times.
According to the invention, the so-called recessed areas are a semi-cylindrical rectangular shape with at least one recessed area and respectively parallel to the surface of the base. The geometry of the recessed area corresponds to the opposite volume of the finger so that the finger can be preferably fixed in the recessed area. For example, when the device is placed on the flat surface of the table, the finger only needs to be placed in the recessed area and the cover can be closed. Therefore, the previous device design needs to use two hands to make the device fixed, and the need to use pressure to press the position of the finger change on the sensor can be avoided one by one.
It must be stated here that the shape of the recessed region can also be an elliptical cross section.
The cover of the device of the present invention comprises a first hinge for opening and closing the cover and the base, and the cover may also comprise a second hinge, which has the advantage that the first hinge and the second hinge are parallel to each other The operation allows the finger diameters of different diameters to be fixed between the cover and the base. In addition, the cover and the base are assembled by simple mechanical means, and the two are connected together without any measurement malfunction due to the inclination of the cover and the base, and the usability of the device is also increased.
It must be noted here that there are many possible ways to tie the cover to the base while the two can move together. For example, a guiding mechanism whose axis and the base are perpendicular to each other causes the cover to move relative to the base in the vertical direction. In particular, the cover of the telescopic telescopic type is also specially designed to be guided on the base. Single or double hinges (one after the other or one parallel) can also be used. Furthermore, the cover and the base are fastened or hinged, and the elastic member or the fastener can be fixed and separated. The special design is that when the cover is opened, it will slowly return to the position where the base is closed. This is different from the prior art, so that the device of the invention can therefore be used comfortably for the individual. That is, the user opens the cover and places at least one finger on the sensor on the surface of the base. When the cover is slowly placed in the closed position, the measurement and recording process can be started. It can be used repeatedly, and the measurement procedure can also be started automatically when the cover is closed.
According to the present invention, the display unit of the apparatus of the present invention is disposed at one end of the cover, facing away from the base, so that the user can read the display unit when the cover is closed. If the display unit can be a touch screen, the user can select different measurement parameters in the actual program. Different physiological parameters can also be determined if needed, using different sensors.
For example, the physiological parameters used include electrocardiogram data, temperature data, blood pressure data, blood oxygen content and tissue oxygen consumption, and even blood glucose measurement.
The pedestal of the device of the present invention can be powered by the battery to the device, and at the same time, because the weight of the battery on the pedestal can be better stabilized on a plane such as a table top, the device can not be inadvertently dumped.
The device of the present invention comprises an analogous and quantitative component, wherein the analog component is disposed on a base, the digital component being disposed at the cover and vice versa. Because the analogy and digital components are separated in the spatial design, they are not interfered with each other, enabling more sensitive physiological parameter measurement and recording, especially when performing digital processing operations without any risk. Therefore, the quality of the entire measurement is improved, and the accuracy and sensitivity of the device of the present invention are relatively increased, and the external disturbance or disturbance is relatively reduced.
The device of the present invention comprises a communication interface, which may be a near field communication interface, such as a Bluetooth or far infrared interface or a USB interface. This communication interface is used to transfer the data recorded by the device of the present invention to an external device. As such, the device of the present invention can be interconnected with a home computer using a USB interface. Therefore, patients can use complex assessment software to understand and evaluate their physiological data. At the same time, this communication method can also use Bluetooth to transmit data to an outside health service center by means of a mobile phone, so as to provide the service center for evaluating the information and using the measured data.
At the same time, the functionality with GPS can be integrated into the wireless communication unit of the device of the present invention. In an emergency medical condition, the device of the present invention can transmit the desired message and location to the ambulance unit and urgently notify the ambulance.
The device of the present invention further includes a light-proof design of the recessed area, and when the finger is placed on the placed surface of the base, the external light source can be prevented from intruding into the recessed area when the cover is placed. The advantage of the light-proofing of the recessed area is that the external light source is prevented from intruding, and the internal measurement by the light sensing method is not affected. The purpose of this light prevention is that the wavelength of some natural light will be close to the measured spectrum when measuring the physiological parameters of the human body. For example, in diagnosing pulse oximeter measurements, the sensor used has two sources, one for radiated visible light and the other for near-red light of different wavelengths of light hitting the body's tissues. Light is scattered from human tissue and can be perceived by a suitable light sensor, such as a photodiode. The intensity of the light sensor is used to determine the oxygen content in the blood. It should be noted here that different sensors should be used for the purpose of measurement. In addition to the photodiodes and electrodes, the sensor can also be a full array of sensors that allow for the measurement of physiological parameters after placement and after a short period of time. Therefore, it is feasible to record ion information in a dynamic manner, such as sodium/potassium information, which can be performed using this measurement technique.
As described above, the sensing element can be on the cover or the base to collect the captured material.
According to the device of the present invention, the outer cover that is occluded is breathable, that is, when the finger is placed in the recessed area, it is prevented from sweating. Unlike previous designs, the wetness of the skin surface can cause unpredictable measurement parameter data, making the measurement results less likely to occur.
According to the device of the present invention, the outer cover that is occluded is a sealed mouth. On the other hand, the outer cover can also be completed by an upper cover or a vertical protrusion of the base below, such as synthetic fiber. Sealed mouth.
According to the device of the invention, it can be connected to an external electrocardiogram (ECG) electrode or an optical metrology sensor. If the electrode data processing of the electrocardiogram (ECG) cannot be performed by placing the hand on the surface of the sensor due to the user's special physiological function, an external electrode of the electrocardiogram (ECG) is required.
The preferred embodiment of the present invention is to place two fingers, that is, one for each of the right and left hands, which is convenient in that two hands can be measured at the same time, and an electrocardiogram (ECG) measurement signal can be taken at a close distance.
The integrated sensor of the device preferably comprises: at least one optical transmitter for illuminating the tissue of the human finger placed on the base; and at least one light sensor for sensing the light scattered after the illumination An electrode can record an electrocardiogram or bioimpedance signal; and a temperature or thermal sensor.
The device of the invention has various measurement modes, and can comprehensively analyze the health state of the human body. A more detailed data capture and evaluation sensor signal is disclosed in the patents WO 2007/017263 A2, WO 2007/017266 A2, WO 2007/028570 A2, WO 2008/061788 A1, WO 2009/033624 A1, WO 2009/ It has been disclosed in 033625 A1 and WO2010/099969 A1. Among the devices of the present invention, the advantages of pulse wave oxygen metering, electrocardiogram, temperature, heat, and bioelectrical impedance are measured. With the integrated evaluation unit of the device, all measurement signals can be detected by a suitable algorithm to detect the body's metabolism. With different measurement modes, high efficiency and high reliability can be achieved by detecting the pathological warnings of the human body. All parameters can be successfully and effectively integrated into a comprehensive indicator, which can explain the generality of the user. The state of health. The combination of all physiological parameters of the device of the present invention also provides a more advantageous and effective non-invasive, indirect feasible measuring device, such as glucose concentration or glucose in blood, which is more feasible than previously published works. .
Another embodiment of the device of the present invention has a pressure sensor that can apply pressure to a finger that is placed on the surface of the base. When the pressure is applied to the finger, the integrated sensor transmits the signal. . This pressure sensing ensures the pressure applied to the finger and if the pressure exceeds the allowable allowable range, the device will send a warning message. On the other hand, it requires pressure and can be used to correct the perceived signal or to assess whether it is consistent with the effects of stress.
Preferably, the device of the present invention is at least one sensor, which is spring-assembled on the upper cover or the lower base, so that there is not too much pressure applied to the finger, thereby avoiding noisy Bad measurement results and findings.
Another aspect of the device of the present invention is that when the finger has been placed, the cover can be automatically rotated into the closed position by the sensing, and the action can be performed by a servo motor or a spring with a damping release. It.
The base or the cover of the device of the present invention may have an open space for exhausting functions, and the purpose of the exhausting is to cool the surface area of the finger and the air, and the bad heat may cause the electronic device to be defective. Because the surface of the finger placement area accumulates heat, it will cause a bad signal.
The device of the present invention can utilize an external interface unit to obtain the evaluated data. The evaluation unit can be programmed from this interface. The advantage of this evaluation unit is that it can separate the action of the program from the hardware of the device. It can also have software to contain important technical information. This technology can be separated by different programs. It can also be uploaded to the memory area of the integrated microcomputer device by using the software, so that the interface can be closed or the software cannot be used or read.

1 is a perspective view of the diagnostic measuring device (100) of the present invention. The geometrical configuration of the diagnostic measuring device (100) according to the present invention is less than 12 cm in length and less than 8 cm in width. The height is less than 3 cm. Therefore, the diagnostic measuring device (100) can be a portable measuring device.
Considering the main components, the diagnostic measuring device (100) comprises a base (102) and a cover (104); in the first figure, the base (102) and the cover (104) have recessed areas. (106), the recessed area (106) helps to adapt the fingers of the human body. As shown in Fig. 1, when the cover (104) is in the open position, the fingers of the human body can be placed in the recessed area (1060, the most stagnant area (116) that is pre-designed to park.
The cover (104) can correctly rotate the cover (104) of the first figure from the open position to the closed position by the first hinge (114) and the second hinge (112) of the base (102). position. When the cover (104) is in the closed position, the finger will be secured in the recessed area (106). Therefore, the finger will not be able to move vertically in the area inside the recessed area (106), and will not be active in the stagnant area (116).
When the axes of rotation of the first hinge (114) and the second hinge (112) are parallel to each other, the extended axis may change the distance of the base (102) from the cover (104) depending on the thickness at which the finger is placed.
The diagnostic measuring device (100) further comprises an evaluation unit (500) but is not shown in Fig. 1, and the physiological parameters of the human body recorded by the sensor (108) can be evaluated in the cover (104) The inner side is opposite to the base (102) and has a display unit (110) as display evaluation information. The display unit (110) is preferably a touch screen, and the different functions of the diagnostic measuring device (100) can be selected in a touch-operated manner. For example, the diagnostic measurement device (100) can independently measure different physiological parameters.
Furthermore, an interface (118) as shown in Fig. 1 can be connected to different external devices. The interface can also be a commercial type USB interface, or a special interface type can be connected to an external ECG device (such as a LEMO connection), by which the device can be controlled, such as reading data.
In addition, at the interface (118), a type of card reader can also provide its use, such as Micro SD, to transfer and write the amount of data to the associated memory card.
Referring to Figures 2A and 2B, which is a side view of the foldable cover (104), the figure clearly shows the cover (104) of the base (102), which can be borrowed from the first hinge. (114) and the second hinge (112) arranging the cover (104) with the base (102); as in Figure 2A, the diagnostic measuring device (100) is in the closed position, and The Fig. 2B shows that the cover (104) is rotated to the closed position by opening, so that it can be completed by a very large number or by a stuck stop. When the cover (104) is to be covered with a finger using a little power, it can be accomplished by the stop of the jam so that the finger can be preferably placed in the recessed area (106).
Referring to Fig. 3, the figure of the cover (104) in which the diagnostic measuring device (100) is fully opened, the integrated sensor (108) indicated in Fig. 1 can be clearly seen. In this FIG. 3, the diagnostic measuring device (100) is provided with a light emitter (302) (such as light-emitting diode LEDs) on the susceptor (102) to generate different wavelengths of light. Suitable light detectors (303), (310) can record light from the LED light emitter (302) and the light signals scattered by the finger between the recessed area (106) and the cover (104).
Referring again to another embodiment shown in FIG. 3, the electrode (304) can record electrocardiogram (ECG) electrodes and biological impedance data. The impedance data of the organism can be recorded by combining the electrode (304) and the electrode (308) in the recessed area (106).
Finally, the diagnostic measuring device (100) has a temperature sensor (306) that records the temperature of the human body when the finger of the human body is placed.
As previously mentioned, the diagnostic measuring device (100) preferably has means for preventing light in the recessed area (106) so as not to affect the measurement of light sensitivity. As shown in Fig. 3, there is a mask (300) with respect to the left recessed area (106). The mask (300) is in the form of a sealed mouth and is placed on the cover (104). Between the pedestals (102), the recessed area (106) can be entirely enclosed.
For example, the mask (300) may be selected to be more easily compressed and preferably made of elastic rubber, because it can be easily pressed in a preferred manner, and can be adapted to the shape on which the finger is placed, so that the recessed area can be made (106). ) The external light is blocked by the design of the mask (300). At the same time, it is also possible to prevent the light emitted inside the diagnostic measuring device (100) from being radiated to the outside.
Please refer to the figure shown in Figures 4a and 4b for the internal diagram of the base (102). In the 4th and 4th diagrams, the module design of the electronic component can be seen at a glance. In addition to the battery (408), the electronic component of the pedestal (102) can comprise a plurality of types of modules, such as an LED module (400). ), an electrocardiogram (ECG) module (402), a temperature recording module (404) or a bioimpedance module (406). As in Figures 4a and 4b, the associated modules can be changed in an appropriate and varied manner. It is conceivable that the diagnostic measuring device (100) can be a basic version allowing subsequent updates to be paired with new modules. For example, at the beginning, only the bioimpedance and temperature are measured, and the user can record the information and the information of the evaluation, and then combine with the electrocardiogram (ECG) module.
As shown in Fig. 5, it is a top view of the cover (1040) of the diagnostic measuring device (100). It can be seen in Fig. 5 that the connecting cover (104) is transmitted through the first hinge (114). Connected to the base (102) (not shown in Fig. 5). The touch display unit (110) is evaluated by the integrated evaluation unit (500) on the cover (104). Display function: The integrated evaluation unit (500) is to evaluate and evaluate the relevant recording parameter data sent by the plurality of sensors, and then transmit the data to the display unit (110).
Further, the touch display unit (110) as described above is used as a specific input material for the user as a general functional control. This can include both a suitable measurement program and the input of personal information, such as the name, age, surname or weight of the individual.
FIG. 6 is a perspective view showing another main component of the diagnostic measuring device (100) of the present invention. The diagnostic measuring device (100) is composed of a base 102 and a cover 104, and the concave portion is formed. The area (106), in turn, can also accommodate the fingers of the human body.
The recessed area (106) (or the generally placed surface layer 106) can be combined with the cover (104) on the side in the lateral direction when the cover (104) is closed, wherein the recess is combined with the cover (104). The trough shape (600) is combined with an oppositely symmetric mask (300). That is, the mask (300) is perpendicular to the cover (104), so that lateral light intrusion and internal prevention of light escape can be avoided.
The mask (300) can be vented through holes or in other configurations to avoid sweating of the fingers or an increase in temperature, thereby damaging diagnostic measurements.
Moreover, the idea of the idea has not been seen in the publication or public use. It is in line with the requirements of the invention patent application, and I would like to ask the Bureau to give it a patent, and to pray.
It is to be understood that the above is the technical principle immediately applied to the specific implementation of the present invention. If the function of the present invention is changed, the functional function produced by the present invention does not exceed the spirit of the specification and the drawings. , should be within the scope of the invention, combined with Chen Ming.

(100). . . Diagnostic measuring device

(102). . . Pedestal

(104). . . Cover

(106). . . Concave area

(108). . . Integrated sensor

(110). . . Display unit

(112). . . Second hinge

(114). . . First hinge

(116). . . Stagnant zone

(118). . . interface

(300). . . Cover

(302). . . Light emitter

(303). . . Light detector

(304). . . electrode

(306). . . Temperature sensor

(308). . . electrode

(310). . . Light detector

(400). . . Module

(402). . . Module

(404). . . Module

(406). . . Module

(408). . . battery

(500). . . Evaluation unit

(600). . . Concave area

Fig. 1 is a perspective view showing the portable diagnostic measuring device of the present invention.

Figure 2a is a side view of the closed state of the portable diagnostic measuring device of the present invention.

Figure 2b is a side view of the open state of the portable diagnostic measuring device of the present invention.

Fig. 3 is a plan view showing the cover of the portable diagnostic measuring device of the present invention.

Figure 4a is a diagram showing the internal configuration of the base of the portable diagnostic measuring device of the present invention.

Figure 4b is another aspect of the internal configuration of the base of the portable diagnostic measuring device of the present invention.

Fig. 5 is a top view showing the cover of the portable diagnostic measuring device of the present invention.

Figure 6 is a perspective view of another embodiment of the portable diagnostic measuring device of the present invention.

(100). . . Diagnostic measuring device

(102). . . Pedestal

(104). . . Cover

(106). . . Concave area

(108). . . Integrated sensor

(110). . . Display unit

(112). . . Second hinge

(114). . . First hinge

(116). . . Stagnant zone

(118). . . interface

Claims (22)

A portable non-invasive diagnostic measuring device (100) capable of recording at least one blood glucose level and/or oxygen content of a human body, wherein the diagnostic measuring device (100) comprises at least a plurality of integrated sensors ( 108, 302, 303, 304, 306, 308, 310) to evaluate parameters and complete evaluation data by recording and an integrated evaluation unit (500); further, the diagnostic measuring device (100) includes a base (102), a cover (104), and a base (102), a first hinge (114) between the cover (104), and the cover (104) and the base (102) can be rotated between the opening and closing by the first hinge (114) Further, the pedestal (102) includes at least two placed skin layers (106), and each of the placed surface layers (106) is disposed with the integrated sensor and is respectively placed and placed on at least two fingers of the human body; Further, the diagnostic measuring device (100) is planned to fix the two fingers between the base (102) and the cover (104), and when the two are in the closed position, the physiological parameters of the human body are recorded. Down, it also includes an integrated display unit (110) to output the evaluation data. A portable non-invasive diagnostic measuring device (100) capable of recording at least one physiological parameter of a human body, wherein the diagnostic measuring device (100) comprises at least a plurality of integrated sensors for recording and an integrated evaluation unit ( 500), the parameter is evaluated and the evaluation data is completed; the diagnostic measuring device (100) includes a base (102) and a cover (104), and the cover (104) can be performed with the base (102) The rotation between opening and closing; wherein the base (102) comprises at least two placed skin layers (106), and the two placed surface layers (106) are respectively disposed with the integrated sensor, and are respectively placed The human body is measured by at least two fingers of the same hand or different hands; and the diagnostic measuring device (100) is planned to fix the two fingers between the base (102) and the cover (104), when in two When the position is closed, the physiological parameters of the human body are thus recorded, and an integrated display unit (110) is included to output and display the evaluation data; wherein the plurality of integrated sensors further comprises: at least one illuminating emitter ( 302), emits light to the body group where the finger is placed At least one photodetector (303, 310) for detecting light reflected from body tissue; an electrode (304, 308) for recording an electrocardiogram or/and a bioimpedance signal; and a temperature or thermal sensor. The diagnostic measuring device (100) according to claim 1 or 2, wherein the device (100) further comprises an external electrocardiographic electrode or/and an optical measuring sensor. The diagnostic measuring device (100) according to the first or second aspect of the patent application, wherein the placed skin layer (106) is set as a recessed area (106). The diagnostic measuring device (100) according to item 4 of the scope of the patent application, wherein the recessed area (106) is in the shape of a recess of at least one semi-cylindrical strip, arranged in parallel from the surface of the base (102). The diagnostic measuring device (100) according to the first or second aspect of the patent application, wherein the base (102) and the cover (104) are folded from each other to be in an open or closed position. The diagnostic measuring device (100) according to the first aspect of the invention, wherein the cover (104) further comprises a second hinge (112), wherein the first hinge (114) and the second hinge are 112) Each has a rotating shaft that operates between parallel axes. The diagnostic measuring device (100) according to claim 1 or 2, wherein the display unit (110) is disposed on a cover surface (104) corresponding to the base (102). The diagnostic measuring device (100) according to claim 1 or 2, wherein the base (102) further comprises a battery holder attached to the base. The diagnostic measuring device (100) according to claim 1 or 2, wherein the base (102) and the cover (104) further comprise analog and digital electronic components, wherein the analog electronic components are disposed on the base (102), wherein the digital electronic component is disposed in the cover (104), or the analog electronic component is disposed in the cover (104), and the digital electronic component is disposed in the base (102) . The diagnostic measuring device (100) according to the first or second aspect of the patent application, wherein the display unit (110) is a fine touch screen. The diagnostic measuring device (100) according to claim 1 or 2, wherein the base (102) or the cover (104) further comprises a communication interface. The diagnostic measuring device (100) according to claim 12, wherein the communication interface is a near field communication interface or a USB interface. A diagnostic measuring device (100) according to item 4 of the scope of the patent application, wherein the recessed area (106) comprises a light-proof mask (300), the cover (104) being closed when the finger is placed In order to avoid light intrusion in the recessed area (106). The diagnostic measuring device (100) according to item 14 of the patent application, wherein the mask (300) is breathable. The diagnostic measuring device (100) according to item 14 of the patent application, wherein the mask (300) is a cover for a sealing lip. The diagnostic measuring device (100) according to claim 14 or 15, wherein the mask (300) is a protrusion that is erected from the upper cover (104) or the lower base (102) Composition. The diagnostic measuring device (100) according to claim 1 or 2, wherein the placed surface layer (106) further comprises a pressure sensor for recording when the finger is placed on the placed surface layer (106). pressure. The diagnostic measuring device (100) according to the first or second aspect of the patent application, wherein at least one sensor (108, 302, 303, 304, 306, 308, 310) is provided with a spring assembly provided on the cover (104) or the base (102). The diagnostic measuring device (100) according to the first or second aspect of the patent application, wherein the diagnostic measuring device (100) is provided with an automatic rotation when the finger is placed on the placed surface layer (106) The cover (104) is automatically rotated from the open position to the closed position. The diagnostic measuring device (100) according to claim 1 or 2, wherein the base (102) and/or the cover (104) have a passage gap of the exhaust gas. The diagnostic measuring device (100) according to claim 1 or 2, wherein the integrated evaluation unit (500) provides an interface for external connections.