CN219331659U - Wearable intelligent glasses for brain function assessment, intervention and treatment - Google Patents

Abstract

The utility model relates to wearable intelligent glasses for brain function evaluation, intervention and treatment, which comprise a glasses body, wherein a control circuit board and a rechargeable battery electrically connected with the control circuit board are arranged in the glasses body; the glasses body is also detachably provided with a headband or a flexible cap body, the headband or the flexible cap body is provided with a second monitoring device and a second intervention adjusting device, the second monitoring device is provided with a plurality of devices and is arranged at positions corresponding to the positions of the international standard guide system 10-20 or 10-10, and the second intervention adjusting device is provided with a plurality of devices and is arranged on the headband or the flexible cap body at the positions adjacent to the second monitoring device. The utility model uses glasses as a carrier, integrates a plurality of devices for monitoring and intervening and adjusting brain functions in a fixed and detachable mode, and is convenient to carry and use.

Description

Wearable intelligent glasses for brain function assessment, intervention and treatment

Technical Field

The utility model relates to portable medical health intelligent equipment, in particular to wearable intelligent glasses for brain function assessment, intervention and treatment.

Background

The mental stress problem faced by human beings is not obviously reduced along with the high-speed development of information technology, and recently, the safety and health problem related to brain eyes is increased or not along with the abuse of electronic screens, particularly smart phones. Cerebral disorders such as cerebral apoplexy, depression, epilepsy, schizophrenia, senile dementia and infantile autism have been plagued by human beings, and no good medical solution has been found. With the great development of medical artificial intelligence technology, the popularization and application of digital information technology combined with artificial intelligence in the field of psychology and medicine are also gradually developed. The portable and wearable digital intelligent product can effectively monitor and prevent and treat heart and brain diseases, and has the advantages of being more timely, convenient, effective or low in cost compared with large-scale instruments and equipment commonly used in hospitals such as nuclear magnetism, CT and the like, which are huge in size and high in cost. Currently, portable eye-movements (e.g., pro glass 3 developed by Tobii, sweden), portable transcranial magnetic stimulation devices (e.g., semi-implantable TMS devices developed by Inner Cosmos, USA), and portable ultrasound devices (e.g., floPatch developed by ButterflyiQ, flosonics Medical, siemens) have been developed internationally, but there is still a lack of wearable smart devices available to date that truly implement a functional closed loop, effectively evaluate and intervene or treat brain dysfunction in a timely manner. Especially, symptom onset of some brain dysfunctions is quite abrupt and has high risk, but the current wearable intelligent devices are single-function and cannot implement closed-loop wearable devices with intervention, regulation and treatment functions in detection so as to effectively realize dynamic management and intelligent control of related diseases.

Disclosure of Invention

Aiming at the existing defects, the utility model provides wearable intelligent glasses for brain function assessment, intervention and treatment.

The technical scheme adopted for solving the technical problems is as follows: the wearable intelligent glasses for brain function evaluation, intervention and treatment comprise glasses bodies, wherein a control circuit board provided with a microprocessor and a rechargeable battery electrically connected with the control circuit board are arranged in the glasses bodies, and a first monitoring device electrically connected with the control circuit board and used for eye brain monitoring and a first intervention regulating device for intervention stimulation of the brain are arranged on the glasses bodies; the pair of glasses is characterized in that the pair of glasses body is also detachably provided with a head band or a flexible cap body, the head band or the flexible cap body is provided with a second monitoring device and a second intervention adjusting device, the second monitoring device can be electrically connected with the control circuit board, the second monitoring device is provided with a plurality of second intervention adjusting devices and is arranged at positions corresponding to the positions of the international standard guide system 10-20 or the international standard guide system 10-10, and the second intervention adjusting device is provided with a plurality of second intervention adjusting devices and is arranged on the head band or the flexible cap body at the positions adjacent to the second monitoring device.

Preferably, the first monitoring device is any one or two of a PPG signal acquisition module and an eye movement tracking module with infrared light sensitivity, the PPG signal acquisition module is arranged on the glasses leg of the glasses body at the position corresponding to the auricular point of the temporal artery and/or the retroauricular artery of the head, and the eye movement tracking module is arranged on the glasses frame of the glasses body at the position corresponding to the cornea of the eye.

Preferably, the first intervention adjusting device is any one or two of a sound stimulation module and a light stimulation module, wherein the sound stimulation module is arranged on the glasses body, and the light stimulation module is arranged on the glasses frame of the glasses body.

Preferably, the sound stimulation module comprises a loudspeaker arranged on the glasses body and an audio chip arranged in the glasses body, wherein the loudspeaker is electrically connected with the sound stimulation module; the light stimulation module is an LED lamp capable of simulating high-frequency brain waves.

Preferably, the second monitoring device is any one or two of a near infrared cerebral blood oxygen module and an EEG signal acquisition module.

Preferably, the second intervention regulating device is any one or more of a transcranial ultrasound module, a transcranial magnetic stimulation module and a transcranial electrical stimulation module.

Preferably, the headband or the flexible cap body is sleeved on the glasses legs of the glasses body, and the headband or the flexible cap body and the glasses legs of the glasses body are respectively provided with an electric connection joint capable of being matched and electrically connected.

Preferably, the glasses body is provided with sliding grooves with T-shaped cross sections on the surfaces of the two glasses legs, any one or each sliding groove is provided with a conductive layer electrically connected with the control circuit board, the headband or the flexible cap body is provided with a sliding block which can be matched and limited and is arranged in the sliding groove in a sliding way, and the surface of the sliding block opposite to the conductive layer is provided with a conductive part electrically connected with the second monitoring device and the second intervention adjusting device.

Preferably, the control circuit board is further provided with an internet of things chip and a wireless communication module, and the internet of things chip is connected with a cloud server through the wireless communication module in a communication manner and is connected with a cloud computing platform and/or an intelligent terminal with an edge computing function through the cloud server in a communication manner.

Preferably, the glasses body is further provided with a charging interface and a switch electrically connected with the control circuit board.

The utility model has the beneficial effects that: the utility model uses glasses as a carrier, integrates a plurality of devices for monitoring and intervening and adjusting brain functions in a fixed and detachable mode, can adopt a corresponding single or a plurality of devices for monitoring and intervening the brain functions according to the use requirement, and is convenient to carry and use.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present utility model;

FIG. 2 is a schematic view of a headband in accordance with an embodiment of the present utility model;

FIG. 3 is a schematic cross-sectional view of a chute on a glasses body according to an embodiment of the present utility model;

part names and serial numbers in the figure: the pair of glasses comprises a glasses body 10, a sliding groove 11, a charging interface 12, a switch 100, a conductive layer 2, a control circuit board 3, a rechargeable battery 4, a first monitoring device 40, a PPG signal acquisition module 41, an eye movement tracking module 5, a first intervention adjusting device 50, a sound stimulation module 51, a light stimulation module 6, a head band 60, a sliding block 600, a conductive part 7, a second monitoring device 70, a near infrared cerebral blood oxygen module 71, an EEG signal acquisition module 8 and a second intervention adjusting device.

Detailed Description

The present utility model will be further described in connection with the following examples which are to be construed as illustrative and not limiting the scope of the utility model. The implementation conditions used in the examples may be further adjusted according to the conditions of the specific manufacturer, and the implementation conditions not specified are generally those in routine experiments. Furthermore, directional terms, such as "upper", "lower", "front", "rear", "left", "right", "inner", "outer", etc., in the present utility model are used only with reference to the directions of the attached drawings, and are used for better and more clear description and understanding of the present utility model, not to indicate or imply the orientations that the present utility model must have, and thus should not be construed as limiting the present utility model.

The embodiment of the utility model is shown in fig. 1 to 3, a wearable intelligent glasses for brain function evaluation, intervention and treatment comprises a glasses body 1, wherein the glasses body 1 comprises a glasses frame, glasses legs arranged on the left side and the right side of the glasses frame and lenses arranged in the glasses frame, a control circuit board 2 provided with a microprocessor and a rechargeable battery 3 electrically connected with the control circuit board 2 are arranged in the glasses body 1, the rechargeable battery 3 supplies power to the control circuit board 2, the microprocessor is used for processing information transmitted by other received parts, the control circuit board 2 and the rechargeable battery 3 are arranged on the glasses frame or the glasses legs of the glasses body 1 according to the use requirement, preferably both the control circuit board 2 and the rechargeable battery 3 are arranged on the glasses legs, a first monitoring device 4 electrically connected with the control circuit board 2 and used for monitoring eyes and brain, a first intervention regulating device 5 for stimulating the brain are arranged on the glasses body 1, after the glasses are worn, the first monitoring device 4 can be used for monitoring the condition of brain functions and transmitting the monitored condition information to the microprocessor of the control circuit board 2 for processing, the microprocessor comprises processing chips for processing various signals, such as PPG, EEG, eye movement information, intracranial vascular blood oxygen parameters and the like, such as CY8C4247LQI-BL483 chips, the first intervention regulating device 5 is used for stimulating the brain so as to realize the functions of intervention, regulation and treatment, the positions capable of being monitored and interfered are the positions of the head corresponding to the glasses body 1, such as the positions of eyes and nose roots corresponding to the glasses frame, the positions of ears corresponding to the glasses legs and the left and right temporal sides of the head, at the moment, the first monitoring device 4 is any one or two of the PPG signal acquisition module 40 and the eye movement tracking module 41 with infrared light sensation, the PPG signal acquisition module 40 is arranged at the position of the temple of the glasses body 1 corresponding to the temporal artery and/or the peripheral site of the retroauricular artery of the head, the eye movement tracking module 41 is arranged at the position of the frame of the glasses body 1 corresponding to the cornea, that is to say, the PPG signal acquisition module 40 is arranged on both the temple of the glasses body 1, the PPG signal acquisition module 40 is in contact with the skin in use, the PPG signal acquisition module 40 is utilized to monitor the condition of pulse wave so as to realize the detection of heart rate, the position of the PPG signal acquisition module 40 can be used for measuring the hydrodynamic parameters of the aortic blood on the left side and the right side, such as the blood flow velocity and the blood oxygen saturation, the PPG signal acquisition module 40 comprises a Light Emitting Diode (LED) and a Photoelectric Detector (PD) which can emit green light, red light and infrared light, and the relevant characteristic information of heart brain diseases can be obtained from the waveform difference of the photoelectric volume pulse wave; the eye movement tracking module 41 is realized by adopting an eyeball tracker, the first intervention regulating device 5 is any one or two of a sound stimulation module 50 and a light stimulation module 51, the sound stimulation module 50 is arranged on the glasses legs of the glasses body 1, the light stimulation module 51 is arranged on the glasses frame of the glasses body 1, and the brain is stimulated by sound and light; the sound stimulation module 50 comprises a loudspeaker arranged on the glasses body 1 and an audio chip arranged in the glasses body 1 which are electrically connected, wherein the inside of the audio chip is burnt with music or sound wave stimulation which can activate the brain or ease the brain in advance, and then the music or sound wave stimulation is played through the loudspeaker; the optical stimulation module 51 is an LED lamp capable of simulating high-frequency brain waves (such as gamma brain waves), the LED lamp can emit flash light of about 40Hz, gamma waves with about the same frequency can be induced in the brain, and the technical principle is reported in journal of Neuron and Cell; the glasses body 1 is also detachably provided with a head band 6 or a flexible cap body, the head band 6 or the flexible cap body is provided with a second monitoring device 7 and a second intervention regulating device 8 which can be electrically connected with the control circuit board 2, namely, the head band 6 or the flexible cap body is arranged on the glasses leg of the glasses body 1, and the head band 6 or the flexible cap body is detachable on the glasses leg, so that the glasses are convenient to carry and use, when the second monitoring device 7 and the second intervention regulating device 8 on the head band 6 or the flexible cap body are needed to be used, the head band 6 or the flexible cap body is arranged on the glasses leg, the soft circuit board is arranged on the head band 6 or the flexible cap body, the second monitoring device 7 and the second intervention regulating device 8 are arranged on the soft circuit board, and then the electric connection joint on the head band 6 or the flexible cap body is electrically connected with the control circuit board 2, the second monitoring device 7 is provided with a plurality of positions corresponding to the positions of the international standard lead systems 10-20 or 10-10, the second monitoring device 7 is arranged on the headband 6 or the flexible cap body, the positions corresponding to the positions of the international standard lead systems 10-20 or 10-10 can be selectively arranged at the positions corresponding to the positions of the international standard lead systems 10-20 or 10-10, or the positions corresponding to all the positions can be arranged according to the use requirement, the second intervention adjusting device 8 is provided with a plurality of positions corresponding to the positions of the second monitoring device 7 on the headband 6 or the flexible cap body, for example, the lead systems of 10-20 are adopted, the second monitoring device 7 is arranged on the headband 6 at the positions corresponding to Cz, C3, T3, C4 and T4, and the lead systems of 10-10 are adopted, and the lead systems corresponding to Cz, C4 and T4 are adopted on the headband 6, the positions of C1, C3, C5, T7, C2, C4, C6 and T8 are respectively selected from several or all points on the left and right sides of the brain, the second monitoring device 7 corresponds to the positions on the head in use, so that the monitoring result is more accurate, a plurality of points are selected for the flexible cap body corresponding to all the points of the 10-20 or 10-10 lead system, the points are uniformly selected on the left and right sides of the brain in the selection process, and a second intervention adjusting device 8 is arranged between the two adjacent second monitoring devices 7. The second monitoring device 7 is any one or two of a near infrared cerebral blood oxygen (fnigs) module 70 and an EEG signal acquisition module 71, for example, the near infrared cerebral blood oxygen module 70 adopts a near infrared-based blood oxygen signal acquisition probe, the probe comprises a light source and a plurality of photoelectric sensors which are electrically connected with the control circuit board 2 and are arranged in a straight line, and the plurality of photoelectric sensors are positioned on the same side of the light source; the EEG signal acquisition module 71 comprises acquisition electrodes, acquisition module chips and analog signal amplification and filtering modules, such as ADS1292, 1294, 1296, 1298 chips correspond to bioelectric acquisition chips of 2, 4, 6, 8 channels, the acquisition electrodes are arranged on the headband 6 or the flexible cap, and the acquisition module chips and analog signal amplification and filtering modules are arranged on the flexible circuit board or integrated on the control circuit board 2, so that the acquisition electrodes are electrically connected with the acquisition electrodes. The second intervention regulating means 8 is any one or more of a transcranial ultrasound module, a transcranial magnetic stimulation module (rTMS) and a transcranial electrical stimulation module (tDCS).

For the detachable of the headband 6 or the flexible cap body on the glasses body 1, one mode is that the headband 6 or the flexible cap body is sleeved on the glasses legs of the glasses body 1, namely, rings matched and arranged on the glasses legs are arranged on the left side and the right side of the headband 6 or the flexible cap body, electric connection joints capable of being matched and electrically connected are respectively arranged on the headband 6 or the flexible cap body and the glasses legs of the glasses body 1, the electric connection joints can be conductive jacks or conductive needles arranged on the glasses legs, then, conductive needles or conductive jacks are arranged on the headband 6 or the flexible cap body, the positions of the electric connection joints arranged on the headband 6 or the flexible cap body are corresponding to the electric connection joints on the glasses legs after the headband 6 or the flexible cap body is sleeved on the glasses legs, and for adopting the mode of the headband 6, the positions of the electric connection joints on the glasses legs are corresponding to the crown lines of the lead systems according to 10-20 or 10-10, namely, the positions of the electric connection joints on the glasses legs can be connected with the Cz, C3, C4, T4, or C4, C1, C3, C5, C7, C4 and T4, and the electric connection joints on the glasses body are arranged on the sides of the glasses body in any mode. The other way is that the surface of the two glasses legs of the glasses body 1 is provided with the sliding groove 10 with a T-shaped cross section, that is, the left glasses leg on the left side of the glasses body 1 and the right glasses leg on the right side of the glasses body are provided with the sliding groove 10, the cross section of the sliding groove 10 is in a T-shaped structure, the sliding direction in the sliding groove 10 is along the direction of the glasses leg, any end of the sliding groove 10 is provided with a socket for inserting the sliding block 60, the T-shaped structure prevents the sliding block 60 from sliding out of the sliding groove 10 in sliding, at the moment, the sliding groove 10 can be arranged on the top surface, the bottom surface, the outer side surface or the inner side surface of the glasses legs, the inner side surface is the surface opposite to the two glasses legs, the cross section of the sliding groove is in an inverted T-shaped structure when arranged on the top surface, the cross section of the sliding groove is in a T-shaped structure when arranged on the bottom surface, the cross section of the sliding groove is in a side T-shaped structure when arranged on the side surface, the sliding groove is preferentially arranged on the top surface or the outer side surface, the glasses are convenient to wear and use, the head band 6 or the flexible cap body is also convenient to mount and use on the glasses body 1, the two groove walls of any one or each of the sliding grooves 10 are respectively provided with a conductive layer 100 electrically connected with the control circuit board 2, the head band 6 or the flexible cap body is provided with a sliding block 60 which can be matched and limited and is arranged in the sliding groove 10 in a sliding way, the surface of the sliding block 60 opposite to the conductive layer 100 is respectively provided with a conductive part 600 electrically connected with the second monitoring device 7 and the second intervention adjusting device 8, the sliding block 60 is matched and is arranged in the sliding groove 10, the section of the sliding groove 10 is of a T-shaped structure, the T-shaped structure is formed between the sliding block 60 and the head band or the flexible cap body, after the sliding block 60 is mounted in the sliding groove 10, the conductive part 600 of the sliding block 60 is abutted against and electrically connected with the conductive layer 100 on the groove wall of the sliding groove 10, and when the conductive layer 100 is arranged in one sliding groove 10, the conductive layers 100 on the two walls of the sliding grooves 10 correspond to two poles of a circuit, and when the conductive layers 100 are arranged in both the sliding grooves 10, the conductive layer 100 in one sliding groove 10 can form the positive pole of the circuit, and the conductive layer 100 in the other sliding groove 10 can form the negative pole of the circuit; for the conductive layer 100, the conductive coating coated on the wall of the chute 10 may be a conductive sheet disposed along the wall of the chute 10, the limiting sliding device may prevent the headband 6 or the flexible cap from being offset in use after being mounted on the glasses body 1, the limiting structure may be implemented by providing an elastically deformable stop at the bottom of the chute 10, for example, two stops are provided to clamp and fix the slider 60, the conductive portion 600 may be a conductive coating coated on the surface of the slider 60 or a conductive component disposed on the surface of the slider 60, the conductive portion 600 is electrically connected to the second monitoring device 7 and the second intervention adjusting device 8 through a wire disposed in the headband 6 or the flexible cap, after the slider 60 is mounted in the chute 10, the headband 6 or the flexible cap is electrically connected to the control circuit board 2 on the glasses body 1 through the conductive layer 100 and the conductive portion 600, and power is provided to the second monitoring device 7 and the second intervention adjusting device 8 through a power supply on the glasses body 1. Thus, by means of the headband 6 or flexible cap, the second monitoring device 7 and the second tamper adjustment device 8 can achieve signal monitoring and target tampering corresponding to either site on the 10-20 or 10-10 lead system.

In order to facilitate further analysis and processing of information monitored by the device at the terminal, an internet of things chip and a wireless communication module are further arranged on the control circuit board 2, the internet of things chip is in communication connection with a cloud server through the wireless communication module, and is in communication connection with a cloud computing platform and/or an intelligent terminal with an edge computing function through the cloud server, and each function can be regulated and controlled through corresponding APP software on the intelligent terminal, so that intelligent and personalized functional intervention or target treatment is further implemented.

In order to facilitate the charging of the rechargeable battery 3 in the glasses body 1 and the control of the intelligent glasses, the glasses body 1 is further provided with a charging interface 11 and a switch 12 which are electrically connected with the control circuit board 2, the switch 12 can be arranged on a glasses frame or a glasses leg of the glasses body 1 according to the use requirement, a touch switch can be arranged, the charging interface 11 is arranged on the glasses leg, and the charging interface 11 is a USB interface.

While the utility model has been described in detail in the foregoing general description and with reference to specific embodiments thereof, it will be apparent to one skilled in the art that modifications and improvements can be made thereto. Accordingly, such modifications or improvements may be made without departing from the spirit of the utility model and are intended to be within the scope of the utility model as claimed.

Claims (10)

1. A wearable smart glasses for brain function assessment, intervention and therapy, characterized by: the pair of glasses comprises a glasses body, wherein a control circuit board provided with a microprocessor and a rechargeable battery electrically connected with the control circuit board are arranged in the glasses body, and a first monitoring device for monitoring the eyes and the brain and a first intervention regulating device for intervening and stimulating the brain which are electrically connected with the control circuit board are arranged on the glasses body; the pair of glasses is characterized in that the pair of glasses body is also detachably provided with a head band or a flexible cap body, the head band or the flexible cap body is provided with a second monitoring device and a second intervention adjusting device, the second monitoring device can be electrically connected with the control circuit board, the second monitoring device is provided with a plurality of second intervention adjusting devices and is arranged at positions corresponding to the positions of the international standard guide system 10-20 or the international standard guide system 10-10, and the second intervention adjusting device is provided with a plurality of second intervention adjusting devices and is arranged on the head band or the flexible cap body at the positions adjacent to the second monitoring device.

2. The wearable intelligent glasses for brain function assessment, intervention and therapy according to claim 1, wherein the first monitoring device is any one or both of a PPG signal acquisition module with infrared light sensation and an eye movement tracking module, the PPG signal acquisition module is arranged on the glasses leg of the glasses body at the position corresponding to the temporal artery of the head and/or the auricular artery, and the eye movement tracking module is arranged on the glasses frame of the glasses body at the position corresponding to the cornea of the eye.

3. The wearable intelligent glasses for brain function assessment, intervention and therapy according to claim 1, wherein the first intervention adjustment means is any one or two of a sound stimulation module and a light stimulation module, the sound stimulation module is arranged on the glasses body, and the light stimulation module is arranged on the glasses frame.

4. The wearable intelligent glasses for brain function assessment, intervention and therapy of claim 3 wherein the sound stimulation module comprises an electrically connected speaker disposed on the glasses body, an audio chip disposed within the glasses body; the light stimulation module is an LED lamp capable of simulating high-frequency brain waves.

5. The wearable intelligent glasses for brain function assessment, intervention and therapy of claim 1 wherein the second monitoring device is any one or both of a near infrared cerebral blood oxygen module and an EEG signal acquisition module.

6. The wearable intelligent glasses for brain function assessment, intervention and therapy of claim 1 wherein the second intervention adjustment means is any one or more of a transcranial ultrasound module, a transcranial magnetic stimulation module and a transcranial electrical stimulation module.

7. The wearable smart glasses for brain function assessment, intervention and therapy of claim 1, wherein: the head band or the flexible cap body is sleeved on the glasses legs of the glasses body, and the head band or the flexible cap body and the glasses legs of the glasses body are respectively provided with an electric connection joint which can be matched and electrically connected.

8. The wearable intelligent glasses for brain function assessment, intervention and treatment according to claim 1, wherein the glasses body is provided with sliding grooves with T-shaped cross sections on the surfaces of two glasses legs, each sliding groove or each sliding groove is provided with a conductive layer electrically connected with a control circuit board, the headband or the flexible cap body is provided with a sliding block capable of being matched and limited and sliding in the sliding groove, and the surfaces of the sliding block opposite to the conductive layers are provided with conductive parts electrically connected with a second monitoring device and a second intervention regulating device.

9. The wearable intelligent glasses for brain function assessment, intervention and treatment according to claim 1, wherein the control circuit board is further provided with an internet of things chip and a wireless communication module, and the internet of things chip is in communication connection with a cloud server through the wireless communication module and is in communication connection with a cloud computing platform and/or an intelligent terminal with an edge computing function through the cloud server.

10. The wearable intelligent glasses for brain function assessment, intervention and treatment according to claim 1, wherein the glasses body is further provided with a charging interface and a switch which are electrically connected with a control circuit board.

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