KR20210133697A - Near-infrared spectroscopy probe for measuring temporal lobe function - Google Patents

Abstract

The present invention relates to a near-infrared spectroscopy probe for measuring temporal lobe function. According to the present invention, the near-infrared spectroscopy probe comprises: a main body worn on a subject's ear; and a signal acquisition unit installed in the main body and acquiring a response signal output in response to a near-infrared signal emitted to the temporal lobe of the subject by functional near-infrared spectroscopy (fNIRS). Accordingly, since a response signal corresponding to the near-infrared signal emitted to the temporal lobe of a subject is acquired, the temporal lobe function of the subject can be tested, thereby providing an advantage of providing an accurate test result for the functions of the temporal lobe.

Description

Near-infrared spectroscopy probe for measuring temporal lobe function

The present invention relates to a near-infrared spectroscopy probe for measuring temporal lobe function, and more particularly, to provide a near-infrared spectroscopy probe for measuring temporal lobe function capable of examining the temporal lobe using functional near-infrared spectroscopy to a subject.

The brain consists of left and right hemispheres, which are divided into four main lobes, the frontal lobe, the temporal lobe, the parietal lobe, and the occipital lobe. The left temporal lobe, which corresponds to the side of the head, is involved in the perception, discrimination and storage of auditory words, numbers, and spoken language, and the right temporal lobe is involved in the perception, discrimination and storage of visual words and patterns.

There is no system proposed to evaluate high-level functional impairment of the brain due to brain damage, and in relation to only functional abnormalities, the prior art evaluation system fixes shapes such as circles, triangles, and squares for visual attention tests. It is limited to the level at which the target stimulus is presented at regular intervals in the center of the monitor, or the target stimulus is selected from one, two, or three rhythms for the examination of auditory attention.

In addition, all conventional evaluation systems have been limited to the extent to which abnormalities are discriminated by comparing with values of a normal group obtained by temporarily accumulating performance performed under certain test conditions. In other words, rather than the relevance to the function of each part of the brain, the result of measuring a specific behavior expressed externally was compared with the norm value collected temporarily for the normal group to determine the presence or absence of abnormality. Therefore, it is impossible to analyze the process of temporal change of the reaction pattern that changes over time, as well as to search for new functions any longer. It is a cumbersome task for researchers, such as having to re-collect it.

Registered Patent Publication No. 10-0341080: Brain function disorder test/evaluation/training system

The present invention was devised to improve the above problems, and a near-infrared spectroscopy probe for measuring temporal lobe function capable of examining the temporal lobe function of the subject by acquiring a response signal corresponding to the near-infrared signal irradiated to the temporal lobe of the subject. Its purpose is to provide

The near-infrared spectroscopy probe for measuring temporal lobe function according to the present invention for achieving the above object includes a main body worn on the ear of a subject, and installed on the main body, and a signal acquisition unit for acquiring a response signal output in response to a near-infrared signal irradiated to the temporal lobe.

The main body is provided with a main body formed so as to be caught in the ear of the examinee, and a pull-in member formed in the main body so as to be drawn into the ear hole of the examinee.

The signal acquisition unit is installed on the main body at least one first measurement unit for acquiring a reaction signal output in response to a near-infrared signal irradiated to the head of the subject opposite to the main body, and the lead-in member is installed and a second measurement unit for acquiring a response signal output in response to the near-infrared signal irradiated into the ear of the subject.

The first measurement unit includes a first irradiation member installed on the main body opposite to the skin of the subject and irradiating the near-infrared signal to the head of the subject, and a reaction outputted from the head of the subject in response to the near-infrared signal and a first receiving member installed on the main body to receive a signal.

The second measuring unit is installed in the lead member to receive a second irradiation member for irradiating the near-infrared signal to the temporal lobe side of the subject, and a reaction signal output from the temporal lobe side of the subject in response to the near-infrared signal and a second receiving member installed on the lead-in member.

Meanwhile, the near-infrared spectroscopy probe for measuring temporal lobe function according to the present invention further includes an auditory stimulation unit installed in the main body to apply an auditory stimulus to the subject.

The auditory stimulus unit includes a first speaker installed on the main body to apply an auditory stimulus to the subject, and a second speaker installed on the lead-in member to apply an auditory stimulus to the subject's ear.

Preferably, the first speaker is installed on the main body so as to be in contact with the skin of the subject, and outputs the input sound information in a bone conduction method.

The main body includes an extension rod extending in the vertical direction, and a ring member formed on the upper end of the extension rod to be convexly curved upward so as to be caught by the subject's ear.

The first measurement unit may be installed on the side of the ring member.

On the other hand, the near-infrared spectroscopy probe for measuring temporal lobe function according to the present invention further includes a shielding member that is installed on the lead-in member and blocks external noise from being introduced into the subject's ear.

The shielding member is formed to protrude in a direction in which an outer diameter is extended so as to be in contact with the skin inside the subject's ear on the retracting member at a position spaced apart from the second speaker by a predetermined distance toward the main body.

The main body may further include a first light reflection prevention layer formed on the main body in an area adjacent to the first measurement unit to prevent the near-infrared signal from being reflected on the main body.

The first light reflection prevention layer is preferably formed by matting the surface of the main body in an area adjacent to the first measurement unit.

The main body may further include a second light reflection prevention layer formed on the lead-in member in an area adjacent to the second measurement unit to prevent the near-infrared signal from being reflected by the lead-in member.

Preferably, the second light reflection prevention layer is formed by matting a surface of the lead-in member in an area adjacent to the second measuring unit.

On the other hand, the near-infrared spectroscopy probe for measuring temporal lobe function according to the present invention further includes a measurement control unit for collecting the response signal by controlling the signal acquisition unit, wherein the measurement control unit controls the first and second irradiation members independently of each other The operation is performed according to a preset order, and reaction signals received through the first and second receiving members may be collected.

The near-infrared spectroscopy technique probe for measuring temporal lobe function according to the present invention obtains a response signal corresponding to the near-infrared signal irradiated to the temporal lobe of the subject and examines the temporal lobe function of the subject. It has the advantage of being able to provide

1 is a perspective view of a near-infrared spectroscopy probe for measuring temporal lobe function according to the present invention;
2 is a conceptual diagram of a wearing state of the near-infrared spectroscopy probe for measuring temporal lobe function of FIG. 1;
3 is a side view of the near-infrared spectroscopy probe for measuring temporal lobe function of FIG. 1;
4 is a block diagram of the near-infrared spectroscopy probe for measuring temporal lobe function of FIG. 1 .

Hereinafter, a near-infrared spectroscopy probe for measuring temporal lobe function according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. Since the present invention can have various changes and can have various forms, specific embodiments are illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to the specific disclosed form, it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention. In describing each figure, like reference numerals have been used for like elements. In the accompanying drawings, the dimensions of the structures are enlarged than the actual size for clarity of the present invention.

Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It is to be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

1 to 4 show a near-infrared spectroscopy probe 100 for measuring temporal lobe function according to the present invention.

Referring to the drawings, the near-infrared spectroscopy probe 100 for measuring temporal lobe function includes a main body 200 worn on the ear of an examinee, and is installed on the main body 200, and performs functional near-infrared spectroscopy (fNIRS). A signal acquisition unit 300 for obtaining a response signal output in response to a near-infrared signal irradiated to the temporal lobe of the subject by (400), and a measurement control unit (500) for providing information on the reaction signal obtained by the signal acquisition unit (300) to the examiner.

The main body 200 includes a main body 210 formed to be hooked on the subject's ear, and a retracting member 220 formed on the main body 210 to be drawn into the subject's ear hole.

The main body 210 includes an extension rod 211 extending in the vertical direction, and a ring member 212 formed on the upper end of the extension rod 211 and curved upwardly convexly so that it can be caught on the subject's ear. be prepared

The extension rod 211 has a predetermined outer diameter and is formed in a round bar shape extending in the vertical direction. The extension rod 211 is preferably made of a synthetic resin material such as plastic having a predetermined strength and excellent moldability.

The ring member 212 extends upward with respect to the upper end of the extension rod 211, and is formed in a semicircular shape to provide a space for the subject's ear to be inserted. At this time, the ring member 212 is installed on the side opposite to the subject's skin, the first measurement unit 310 of the signal acquisition unit 300 to be described later.

In addition, the ring member 212 has a first light reflection prevention layer 213 is formed in order to prevent the near-infrared signal generated by the first measurement unit 310 from being reflected. The first light reflection prevention layer 213 is formed to cover the outer peripheral surface of the ring member 212 in the area adjacent to the first measurement unit 310 . Here, the first light reflection preventing layer 213 is formed on the outer peripheral surface of the ring member 212 by matting black. At this time, the first light reflection preventing layer 213 is not limited thereto, and a black matt ceramic material or rubber material may be applied.

Meanwhile, in the illustrated example, the structure in which the first light reflection prevention layer 213 is formed on the ring member 212 is illustrated, but the present invention is not limited thereto and may be formed on the main rod.

The pull-in member 220 extends in a direction crossing the extension direction of the main rod at the lower end of the main rod. The lead-in member 220 is formed in a conical shape so that the outer diameter decreases as the distance from the main rod so that the end can be easily drawn into the ear hole of the subject. In addition, the lead-in member 220 is preferably formed of a synthetic resin material such as plastic having a predetermined strength and excellent moldability. A second measurement unit 320 of the signal acquisition unit 300 and a second speaker 402 of the auditory stimulation unit 400 are installed at an end of the lead-in member 220 .

In addition, the lead-in member 220 has a second light reflection preventing layer 221 is formed to prevent the near-infrared signal generated by the second measurement unit 320 from being reflected. The second light reflection prevention layer 221 is formed to cover the outer peripheral surface of the lead-in member 220 in the area adjacent to the second measurement unit 320 . Here, the second light reflection preventing layer 221 is formed by matting the outer peripheral surface of the end of the lead-in member 220 with black. In this case, the second light reflection preventing layer 221 is not limited thereto, and a black matt ceramic material or rubber material may be applied.

On the other hand, the lead-in member 220 is provided with a shielding member 222 to block the inflow of external noise into the subject's ear. The shielding member 222 is in the direction in which the outer diameter is expanded so as to be in contact with the skin inside the subject's ear to the inlet member 220 at a position spaced a predetermined distance from the second speaker 402 to the main body 210 side. protrusion is formed. At this time, the shielding member 222 is formed in a hemispherical shape such that the outer diameter decreases toward the end of the lead-in member 220, and is preferably formed of a rubber material having a predetermined elasticity. The above-described shielding member 222 blocks the inflow of external noise into the examinee's ear, so that the auditory stimulus output to the second speaker 402 is more easily provided to the examinee.

The signal acquisition unit 300 is installed on the main body 210 and a plurality of first measurement units for acquiring response signals output in response to the near-infrared signal irradiated to the head of the subject opposite to the main body 210 . and a second measurement unit 320 installed on the lead-in member 220 and configured to obtain a response signal output in response to the near-infrared signal irradiated into the ear of the subject.

The first measurement unit 310 corresponds to the first irradiation member 311 installed on the main body 210 facing the subject's skin and irradiating the near-infrared signal to the subject's head, and the near-infrared signal. and a first receiving member 312 installed in the main body 210 so as to receive a reaction signal output from the head of the subject.

The first irradiation member 311 is installed on the ring member 212 of the main body 210 opposite to the head of the subject, and irradiates a near-infrared signal, that is, near-infrared light, to the skin of the subject corresponding to the temporal lobe, 730 nm An LED that generates light with a wavelength or 850 nm wavelength is applied.

The first receiving member 312 is installed on the ring member 212 at a position adjacent to the first irradiation member 311 . The first receiving member 312 responds to the near-infrared signal irradiated from the first irradiating member 311 or the second irradiating member 321 of the second measuring unit 320 to be described later, a response signal output from the temporal lobe of the subject That is, an optical sensor capable of receiving a hemodynamic fNIRS signal is applied. The first receiving member 312 transmits the received response signal to the measurement control unit 500 .

On the other hand, in the illustrated example, the structure is shown in which a plurality of first measurement units 310 are installed on the ring member 212, but the first measurement unit 310 is not limited thereto, but one or three or more rings. It may be installed on the member 212 .

The second measurement unit 320 includes a second irradiation member 321 that is installed on the lead-in member 220 and irradiates the near-infrared signal to the temporal lobe of the examinee, and in response to the near-infrared signal from the temporal lobe of the examinee. A second receiving member 322 installed on the lead-in member 220 is provided so as to receive the output reaction signal.

The second irradiation member 321 is installed at the end of the pull-in member 220 that is inserted into the ear hole of the subject, and irradiates a near-infrared signal, that is, near-infrared light, toward the temporal lobe. An LED that generates light with a wavelength of 730 nm or 850 nm is applied do. In this case, the second irradiation member 321 is preferably installed on the upper outer peripheral surface of the lead-in member 220 so that the near-infrared signal is irradiated toward the temporal lobe rather than the eardrum.

The second receiving member 322 is installed on the upper outer peripheral surface of the inlet member 220 at a position adjacent to the second irradiation member 321 . The second receiving member 322 may receive a reaction signal output from the temporal lobe of the subject in response to the near-infrared signal irradiated from the first irradiating member 311 or the second irradiating member 321, that is, a hemodynamic fNIR signal. An optical sensor is applied. The second receiving member 322 transmits the received response signal to the measurement control unit 500 .

The auditory stimulation unit 400 is installed on the main body 210 to apply the auditory stimulation to the first speaker 401 and the lead-in member 220 is installed to apply the auditory stimulation to the subject's ear. and a second speaker 402 that

The first speaker 401 is installed on the ring member 212 of the main body 210, and is installed on the outer surface of the ring member 212 opposite to the subject's skin. In this case, the first speaker 401 may be installed on the surface of the first light reflection prevention layer 213 . Here, the first speaker 401 is installed on the main body 210 so as to be in contact with the skin of the subject, and outputs the entered sound information in a bone conduction method.

The second speaker 402 is installed at the end of the lead-in member 220 to output sound information written in the ear hole of the subject. In this case, the second speaker 402 is preferably installed on the second light reflection preventing layer 221 . Here, the sound information includes a sound stimulus of 40 Hz along with music.

The measurement control unit 500 controls the signal acquisition unit 300 to collect the reaction signal. The measurement control unit 500 operates the auditory stimulation unit and operates the first and second irradiation members 311 and 321 independently of each other when a test start signal is input from the examinee after the subject wears the body 200, It operates according to a set sequence and collects response signals received through the first and second receiving members 312 and 322 .

For example, the measurement control unit 500 operates the second irradiation member 321 inserted into the ear of the subject after the auditory stimulation unit is operated, and collects the reaction signals received from the first and second receiving members 312 and 322 . do. Next, the measurement control unit 500 stops the second irradiation member 321, operates one of the first irradiation members 311, and then responds to the reaction signals received from the first and second receiving members 312 and 322. collect Next, the measurement control unit 500 stops the actuated first irradiation member 311, operates the other one of the first irradiation members 311, and then the first and second receiving members 312 and 322 received Collect response signals.

The measurement control unit 500 may include a communication module (not shown) to transmit the received response signal to the management server or the terminal of the examiner.

The near-infrared spectroscopy technique probe 100 for measuring temporal lobe function according to the present invention configured as described above acquires a response signal corresponding to the near-infrared signal irradiated to the temporal lobe of the subject to examine the temporal lobe function of the subject, so the function of the temporal lobe It has the advantage of being able to provide more accurate inspection results for

The description of the presented embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the invention. Thus, the present invention is not intended to be limited to the embodiments presented herein, but is to be construed in the widest scope consistent with the principles and novel features presented herein.

100: near-infrared spectroscopy probe for measuring temporal lobe function 200: body
210: main body 211: extension rod
212: ring member 213: first light reflection prevention layer
220: inlet member 221: second light reflection prevention layer
222: shielding member 300: signal acquisition unit
310: first measuring unit 311: first irradiation member
312: first receiving member 320: second measuring unit
321: second irradiation member 322: second receiving member
400: auditory stimulation unit 401: first speaker
402: second speaker 500: measurement control unit

Claims (17)

a body worn on the subject's ear; and
A signal acquisition unit that is installed in the main body and acquires a response signal output in response to a near-infrared signal irradiated to the temporal lobe of the subject by functional near-infrared spectroscopy (fNIRS);
Near-infrared spectroscopy probe for measuring temporal lobe function.
According to claim 1,
the body is
a main body formed so as to be caught on the subject's ear; and
Having; a retracting member formed on the main body so as to be drawn into the ear canal of the subject;
Near-infrared spectroscopy probe for measuring temporal lobe function.
3. The method of claim 2,
The signal acquisition unit
at least one first measurement unit installed on the main body and configured to obtain a response signal output in response to a near-infrared signal irradiated to the head of the subject opposite to the main body; and
a second measurement unit installed on the lead-in member to obtain a response signal output in response to the near-infrared signal irradiated into the ear of the subject;
Near-infrared spectroscopy probe for measuring temporal lobe function.
4. The method of claim 3,
The first measurement unit is
a first irradiation member installed on the main body opposite to the skin of the subject and irradiating the near-infrared signal to the head of the subject; and
A first receiving member installed on the main body to receive a reaction signal output from the head of the subject in response to the near-infrared signal;
Near-infrared spectroscopy probe for measuring temporal lobe function.
4. The method of claim 3,
The second measurement unit is
a second irradiating member installed on the lead-in member to irradiate the near-infrared signal toward the temporal lobe of the subject; and
a second receiving member installed in the lead-in member to receive a response signal output from the temporal lobe side of the subject in response to the near-infrared signal;
Near-infrared spectroscopy probe for measuring temporal lobe function.
3. The method of claim 2,
Further comprising; an auditory stimulation unit installed in the main body so as to apply the auditory stimulation to the subject;
Near-infrared spectroscopy probe for measuring temporal lobe function.
7. The method of claim 6,
The auditory stimulation unit
a first speaker installed on the main body to apply an auditory stimulus to the subject; and
A second speaker installed on the lead-in member to apply an auditory stimulus in the ear of the subject;
Near-infrared spectroscopy probe for measuring temporal lobe function.
8. The method of claim 7,
The first speaker is installed on the main body so as to be in contact with the skin of the subject, and outputs the entered sound information in a bone conduction method,
Near-infrared spectroscopy probe for measuring temporal lobe function.
4. The method of claim 3,
The main body is
an extension rod extending in the vertical direction; and
A ring member formed on the upper end of the extension rod and formed to be convexly curved upward so as to be caught by the subject's ear;
Near-infrared spectroscopy probe for measuring temporal lobe function.
10. The method of claim 9,
The first measurement unit is installed on the side of the ring member,
Near-infrared spectroscopy probe for measuring temporal lobe function.
8. The method of claim 7,
Further comprising a; shielding member installed on the lead-in member to block the inflow of external noise into the ear of the subject;
Near-infrared spectroscopy probe for measuring temporal lobe function.
12. The method of claim 11,
The shielding member is formed to protrude in a direction in which an outer diameter is extended so as to contact the skin in the ear of the subject on the inlet member at a position spaced apart from the second speaker by a predetermined distance toward the main body,
Near-infrared spectroscopy probe for measuring temporal lobe function.
4. The method of claim 3,
The main body further includes a first light reflection prevention layer formed on the main body in a region adjacent to the first measurement unit to prevent the near-infrared signal from being reflected on the main body,
Near-infrared spectroscopy probe for measuring temporal lobe function.
14. The method of claim 13,
The first light reflection prevention layer is formed by matting the surface of the main body in an area adjacent to the first measurement unit,
Near-infrared spectroscopy probe for measuring temporal lobe function.
4. The method of claim 3,
The main body further comprises a second light reflection prevention layer formed on the lead-in member in an area adjacent to the second measurement unit to prevent the near-infrared signal from being reflected by the lead-in member,
Near-infrared spectroscopy probe for measuring temporal lobe function.
16. The method of claim 15,
The second light reflection prevention layer is formed by matting the surface of the lead-in member in the area adjacent to the second measurement unit,
Near-infrared spectroscopy probe for measuring temporal lobe function.
5. The method of claim 4,
Further comprising; a measurement control unit to control the signal acquisition unit to collect the reaction signal;
The second measurement unit is
a second irradiating member installed on the lead-in member to irradiate the near-infrared signal toward the temporal lobe of the subject; and
and a second receiving member installed in the lead-in member so as to receive a response signal output from the temporal lobe side of the subject in response to the near-infrared signal;
The measurement control unit operates the first and second irradiation members independently of each other, operates according to a preset order, and collects reaction signals received through the first and second receiving members,
Near-infrared spectroscopy probe for measuring temporal lobe function.

Images