CN115998329A - Adhesive ultrasonic probe device - Google Patents

Abstract

The invention discloses an adhesive ultrasonic probe device which comprises an adhesive layer and a covering layer, wherein the adhesive layer is used for being adhered to human skin, and a sealed accommodating cavity is formed between the adhesive layer and the covering layer. The ultrasonic probe device further comprises a plurality of groups of ultrasonic probes arranged in the accommodating cavity, each group of ultrasonic probes comprises an emitter and a receiver which are adjacently arranged, the plurality of groups of ultrasonic probes are arranged on the adhesive layer at intervals in an array, and the accommodating cavity is filled with liquid gel. The adhesive ultrasonic probe device provided by the invention can be adhered to a body part to be detected by a patient by the patient, can realize continuous ultrasonic detection and imaging for 24 hours or more, can capture the change images of all organs of the patient when the patient performs various activities, and greatly widens the application scene of the ultrasonic imaging technology, so that the operation mode of the ultrasonic imaging technology is greatly simplified, and is convenient and quick.

Description

Adhesive ultrasonic probe device

Technical Field

The invention relates to the field of medical supplies, in particular to a sticking type ultrasonic probe device.

Background

Ultrasound imaging is a safe, non-invasive way of physical examination that provides a clinician with real-time images of the internal organs of a patient and is diagnosed and analyzed by persons with specialized medical knowledge. Currently, ultrasound imaging relies on cumbersome specialized equipment that is typically available only to specialized medical institutions. In order to capture an ultrasound image, a patient is required to lie or sit still in a medical room, an ultrasound stick and an ultrasound probe are manipulated by a trained technician to guide the ultrasound to different parts of the patient's body, the ultrasound is reflected back from the patient's body and then received by the ultrasound probe, and a high resolution image of deep organs such as the patient's heart, lungs, etc. is formed on an ultrasound imager.

The existing ultrasonic imaging technology has at least the following defects: (1) The patient needs to go to a professional medical institution, and the professional medical staff performs operation and examination, so that more time is consumed; (2) The specific detection steps are complicated, a doctor firstly smears liquid gel on the skin of a patient, then moves the detection area of the ultrasonic probe back and forth close to the skin, and observes imaging and records while moving, so that labor is wasted; (3) Imaging and continuous imaging cannot be operated for a long period of time because the liquid gel flows and dries over time, interrupting imaging, and thus only the physical condition of the patient in the medical room for a short period of time while remaining stationary can be observed, and continuous ultrasound detection of the patient in daily activities cannot be performed. In summary, the existing ultrasonic imaging technology and equipment thereof have the problems of higher cost, poor convenience, limited use scene and the like.

Disclosure of Invention

The invention aims at solving the problems existing in the prior art and provides a paste type ultrasonic probe device which is convenient to use and has less restriction on use scenes.

In order to achieve the above purpose, the invention adopts the following technical scheme:

the utility model provides an paste formula ultrasonic probe device, ultrasonic probe device includes paste layer and overburden, paste the layer and be used for adhering to human skin, paste the layer with form sealed holding the chamber between the overburden, ultrasonic probe device is still including setting up multiunit ultrasonic probe in holding the chamber, every group ultrasonic probe all includes transmitter and the receiver that the adjacent setting, multiunit ultrasonic probe is in be array interval arrangement on the paste layer, hold and be full of liquid gel in the chamber.

In some embodiments, the adhesive layer and the cover layer are both made of flexible materials, and a release layer is also detachably provided on the outer side of the adhesive layer along the thickness direction of the ultrasonic probe device.

In some embodiments, the ultrasonic probe device further comprises a flexible circuit board and a control board, the flexible circuit board is arranged in the accommodating cavity, the flexible circuit board is arranged between the ultrasonic probe and the cover layer along the thickness direction of the ultrasonic probe device, all the ultrasonic probes are electrically connected with the flexible circuit board, and the control board is electrically connected with the flexible circuit board.

In some embodiments, the adhesive layer includes a main body portion and an extension portion, the main body portion and the extension portion are integrally disposed, the accommodating cavity is formed between the main body portion and the cover layer, and the control board is fixedly disposed on the extension portion.

In some embodiments, the control board includes a power source for powering all of the ultrasound probes.

In some embodiments, the control board is configured to receive detection signals of the receivers in all the ultrasound probes in real time, and output the detection signals to a terminal device in real time and generate an ultrasound image.

In some embodiments, the terminal device is an ultrasonic imager, and the control board is electrically or signally connected to the ultrasonic imager.

In some embodiments, the control board includes a wireless signal transmitting device, where the wireless signal transmitting device is configured to wirelessly transmit the detection signal to the terminal device, and the wireless transmission manner includes one or more of WiFi, 5G, and bluetooth.

In some embodiments, the terminal device comprises a cloud data processing center and/or a mobile device, the terminal device being capable of analyzing the ultrasound image by means of artificial intelligence algorithms.

In some embodiments, the ultrasound probe apparatus is disposable.

Due to the application of the technical scheme, the adhesive ultrasonic probe device provided by the invention contains the transmitter and the receiver required by ultrasonic imaging and the liquid gel capable of being reserved for a long time, so that a patient can adhere the ultrasonic probe device to a body part to be detected by himself, and continuous ultrasonic detection and imaging for 24 hours or longer can be realized. The ultrasonic probe device does not need to be operated by a professional technician, and a patient can bring the ultrasonic probe device home from a hospital and purchase the ultrasonic probe device even in a pharmacy, so that the operation mode of the ultrasonic imaging technology is greatly simplified, and the ultrasonic probe device is convenient and quick. Furthermore, the ultrasonic probe device is a wearable imaging product, has lasting adhesive force, and can capture the change images of all organs of a patient when the patient performs various activities (including sitting, standing, jogging and riding a bicycle), thereby greatly widening the application scene of the ultrasonic imaging technology. In conclusion, the ultrasonic probe can replace the existing ultrasonic probe device, and is hopeful to make ultrasonic imaging technology become popular and convenient like band-aid.

Drawings

In order to more clearly illustrate the technical solution of the present invention, the drawings used in the description of the embodiments will be briefly described.

FIG. 1 is a schematic perspective view of an adhesive ultrasonic probe apparatus according to an embodiment of the present invention when the apparatus is adhered to skin;

fig. 2 is a schematic side view of the adhesive ultrasonic probe apparatus of the present embodiment when adhered to the skin;

fig. 3 is a schematic top view of the adhesive ultrasonic probe apparatus of the present embodiment;

FIG. 4 isbase:Sub>A schematic cross-sectional view A-A of FIG. 3;

fig. 5 is an enlarged schematic view at B in fig. 4.

Wherein: 100. an adhesive layer; 110. a main body portion; 120. an extension; 130. a release layer; 200. a cover layer; 201. a receiving chamber; 310. an ultrasonic probe; 311. a transmitter; 312. a receiver; 320. a liquid gel; 330. a flexible circuit board; 400. a control board; 500. skin.

Detailed Description

Preferred embodiments of the present invention will be described in detail below with reference to the attached drawings so that the advantages and features of the present invention can be more easily understood by those skilled in the art.

Referring to fig. 1 to 5, a bonding type ultrasonic probe apparatus includes a bonding layer 100 and a cover layer 200. Wherein, the adhesive layer 100 is used for adhering to the human skin 500, and a sealed accommodating cavity 201 is formed between the adhesive layer 100 and the cover layer 200. The ultrasonic probe device further comprises a plurality of groups of ultrasonic probes 310 arranged in the accommodating cavity 201, each group of ultrasonic probes 310 comprises a transmitter 311 and a receiver 312 which are adjacently arranged, the plurality of groups of ultrasonic probes 310 are arranged on the adhesive layer 100 at intervals in an array, and the accommodating cavity 201 is filled with liquid gel 320. The transmitter 311 is used for converting an electrical signal into an ultrasonic signal and guiding the ultrasonic signal into a human body, the receiver 312 is used for receiving the ultrasonic signal reflected by the human body and outputting the ultrasonic signal to the outside, and the liquid gel 320 is used for isolating air and ensuring effective transmission of the ultrasonic signal.

Referring to fig. 1 and 2, in the present embodiment, the entire ultrasonic probe apparatus is flat, the thickness of the accommodating cavity 201 is approximately equal to the height of one emitter 311 or one receiver 312, and a gap is left between the emitter 311 and the receiver 312, which are relatively close to one side of the cover layer 200, and the adhesive layer 100, and the gap can be filled with the liquid gel 320. The adhesive layer 100 and the cover layer 200 are directly sealed and bonded to each other at the peripheral portion of the housing chamber 201. The ultrasonic probe device is light, thin, small and exquisite in whole, similar to a band-aid in appearance, and has no burden when being stuck on a body.

Referring to fig. 1 and 2, in the present embodiment, the adhesive layer 100 and the cover layer 200 are made of flexible materials, and have a certain elasticity, and can bend and deform along with muscle movement and stretching of the skin 500, so as to ensure that the ultrasonic probe apparatus is always attached to the skin 500 without leaving a gap, and also without increasing inconvenience and discomfort of a patient. Further, in the present embodiment, the transmitters 311 and the receivers 312 in each group of the ultrasonic probes 310 are arranged at intervals, and all the gaps are filled with the liquid gel 320. That is, all the transmitters 311 and the receivers 312 in the accommodating cavity 201 are alternately and uniformly arranged at intervals one by one, and are arranged in an array in the rectangular accommodating cavity 201, so that a space is reserved for bending deformation of the adhesive layer 100 and the cover layer 200, and the adhesive layer 100 and the cover layer 200 are allowed to squeeze or stretch the adjacent transmitters 311 and receivers 312 in the deformation process, so that the working effect of the ultrasonic probe device is ensured. In this embodiment, no matter how the ultrasonic probe device is deformed, the liquid gel 320 is always sealed in the accommodating cavity 201, so that the liquid gel 320 is ensured not to dry up, and no air is left between each group of ultrasonic probes 310 and the human skin 500, which is helpful for efficiently transmitting ultrasonic waves between each group of ultrasonic probes 310 and the viscera of the human body, so as to form a clear and accurate image.

In this embodiment, the release layer 130 is also provided on the outer side of the adhesive layer 100 in a peelable manner along the thickness direction of the ultrasonic probe device. When the ultrasonic probe device is packaged and sold, the release layer 130 is attached to the outer side of the adhesive layer 100, so that the glue on the adhesive layer 100 is protected; when the patient unpacks and uses, the adhesive layer 100 can be adhered to the skin 500 by only peeling the release layer 130, so that the use is very convenient.

Referring to fig. 3 to 5, in the present embodiment, the ultrasound probe apparatus further includes a flexible circuit board 330 and a control board 400. Wherein, the flexible circuit board 330 is disposed in the accommodating cavity 201, and along the thickness direction of the ultrasonic probe device, the flexible circuit board 330 is disposed between the ultrasonic probes 310 and the cover layer 200, all the ultrasonic probes 310 are electrically connected with the flexible circuit board 330, and the control board 400 is electrically connected with the flexible circuit board 330.

Referring to fig. 3, in the present embodiment, the adhesive layer 100 includes a main body 110 and an extension 120, the main body 110 and the extension 120 are integrally disposed, a receiving cavity 201 is formed between the main body 110 and the cover 200, and a control board 400 is fixedly disposed on the extension 120. As can be seen from the figure, in the present embodiment, the main body 110 and the extension 120 are respectively in rectangular film shape, the area of the extension 120 is smaller than that of the main body 110, and the extension 120 is located at one side of the main body 110. In other embodiments, the specific shapes of the main body 110 and the extension 120 are not limited to the form of the present embodiment, and any shape that is convenient to carry and use, such as a circle, a polygon, an irregular shape, etc., may be adopted.

Referring to fig. 4 and 5, in the present embodiment, the control board 400 is a small chip, and at least includes a power source, and the power source is electrically connected to each set of ultrasonic probes 310 through the flexible circuit board 330, so as to supply power to all the ultrasonic probes 310. Further, the control board 400 includes an electronic component such as a microprocessor, and can be connected with all the ultrasonic probes 310 in a signal manner, and is configured to receive detection signals of the receivers 312 in all the ultrasonic probes 310 in real time, output the detection signals to the terminal device in real time, and generate an ultrasonic image. Specifically, under the power supply of the power supply, the transmitter 311 in each group of ultrasonic probes 310 transmits ultrasonic waves into the patient at certain time intervals, and the ultrasonic waves are received by the corresponding receiver 312 after being reflected from the patient. The control board 400 receives a large number of detection signals at different positions, and can be summarized into complete image information, so that a visual image for observation is formed through the terminal equipment. The ultrasonic probe device provided by the embodiment has low cost, can be disposable, is disposable, and is convenient and sanitary.

In some embodiments, the terminal device is an ultrasonic imager (not shown), and the control board 400 is electrically or signally connected to the ultrasonic imager. At this time, the patient needs to be in a room, and after the ultrasonic probe device is stuck to the part to be detected, the control board 400 is connected with the ultrasonic imaging instrument through a data line or the like, so that the detection signal of the ultrasonic probe device can be transmitted to the ultrasonic imaging instrument in real time for imaging. Under this kind of application scenario, the patient still needs to go to medical institution, accepts short-time detection, but the patient just can be by oneself should paste the ultrasonic probe device to the body on, need not to lie flat, also need not the handheld ultrasonic stick operation of professional doctor, can realize self-service detection, and convenience is showing and is improving.

In other embodiments, the control board 400 includes a wireless signal transmitting device, where the wireless signal transmitting device is configured to wirelessly transmit the detection signal to the terminal device, and the wireless transmission manner includes one or more of WiFi, 5G, and bluetooth, which can be extended to various wireless transmission manners in the prior art. At this time, the terminal device comprises a cloud data processing center and/or a mobile device, and the terminal device can analyze the ultrasonic image by means of an artificial intelligence algorithm. In use, the patient can take the ultrasound probe apparatus home or purchase it directly from a pharmacy without leaving the room for detection. The patient can paste the ultrasonic probe device on the part to be detected, can freely move after being pasted, and is engaged in daily activities, diets and light-weight exercises, and the ultrasonic probe device is completely free from being bound by cables and the like. Meanwhile, the ultrasonic probe device can continuously carry out ultrasonic imaging on the body part of the patient for 24 hours or even 48 hours, so that the change condition of the body organ of the patient in daily activities is reflected more truly. In this embodiment, the signal output by the ultrasonic probe device may be wirelessly transmitted to the cloud data processing center, and the doctor may log in the cloud data processing center from his own computer, remotely observe the ultrasonic image of the patient, and perform diagnosis and analysis. In addition, the patient can log in the cloud data processing center from the electronic equipment such as a mobile phone, a tablet, a computer and the like, check the ultrasonic image detected in real time, check the diagnosis report of a doctor, and obtain the preliminary diagnosis information obtained by the artificial intelligence through big data analysis, so that the patient can know the disease condition of the patient anytime and anywhere, and the ultrasonic imaging technology is further simplified and facilitated.

In summary, the ultrasonic probe apparatus provided in this embodiment is convenient to use, does not need to be operated by a professional technician, can be stably attached to the body of a patient for a long time, continuously outputs clear and stable images, and can be transmitted to a terminal device in a wired or wireless mode, thereby providing bidirectional convenience for the patient and a doctor, being expected to replace the existing ultrasonic probe apparatus, and enabling the ultrasonic imaging technology to be more popular and convenient like a band-aid.

The above embodiments are only for illustrating the technical concept and features of the present invention, and are intended to enable those skilled in the art to understand the content of the present invention and to implement the same, but are not intended to limit the scope of the present invention, and all equivalent changes or modifications made according to the spirit of the present invention should be included in the scope of the present invention.

Claims (10)

1. A paste type ultrasonic probe device, characterized in that: the ultrasonic probe device comprises an adhesive layer and a covering layer, wherein the adhesive layer is used for being adhered to human skin, a sealed accommodating cavity is formed between the adhesive layer and the covering layer, the ultrasonic probe device further comprises a plurality of groups of ultrasonic probes arranged in the accommodating cavity, each group of ultrasonic probes comprises an emitter and a receiver which are adjacently arranged, the ultrasonic probes are arranged on the adhesive layer at an array interval, and the accommodating cavity is filled with liquid gel.

2. A stick-type ultrasonic probe apparatus according to claim 1, wherein: the adhesive layer and the covering layer are made of flexible materials, and a release layer is arranged on the outer side of the adhesive layer in a peelable manner along the thickness direction of the ultrasonic probe device.

3. A stick-type ultrasonic probe apparatus according to claim 1, wherein: the ultrasonic probe device further comprises a flexible circuit board and a control board, wherein the flexible circuit board is arranged in the accommodating cavity, the flexible circuit board is arranged between the ultrasonic probe and the covering layer along the thickness direction of the ultrasonic probe device, all the ultrasonic probes are electrically connected with the flexible circuit board, and the control board is electrically connected with the flexible circuit board.

4. A stick-type ultrasonic probe apparatus according to claim 3, wherein: the pasting layer comprises a main body part and an extending part, the main body part and the extending part are integrally arranged, the accommodating cavity is formed between the main body part and the covering layer, and the control board is fixedly arranged on the extending part.

5. A stick-type ultrasonic probe apparatus according to claim 3, wherein: the control board comprises a power supply for supplying power to all the ultrasonic probes.

6. A stick-type ultrasonic probe apparatus according to claim 3, wherein: the control board is used for receiving detection signals of the receivers in all the ultrasonic probes in real time, outputting the detection signals to the terminal equipment in real time and generating an ultrasonic image.

7. A stick-type ultrasonic probe apparatus according to claim 6, wherein: the terminal equipment is an ultrasonic imaging instrument, and the control panel is electrically connected or in signal connection with the ultrasonic imaging instrument.

8. A stick-type ultrasonic probe apparatus according to claim 6, wherein: the control panel comprises a wireless signal transmitting device, wherein the wireless signal transmitting device is used for transmitting the detection signal to the terminal equipment in a wireless mode, and the wireless transmission mode comprises one or more of WiFi, 5G and Bluetooth.

9. A stick-type ultrasonic probe apparatus according to claim 8, wherein: the terminal device comprises a cloud data processing center and/or a mobile device, and can analyze the ultrasonic image by means of an artificial intelligence algorithm.

10. A stick-type ultrasonic probe apparatus according to any one of claims 1 to 9, wherein: the ultrasonic probe device is disposable.

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