JP2009142491A - Optical cerebral function imaging apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical cerebral function imaging apparatus capable of preventing a device structure from becoming complicated and a cost from increasing, solving the problem caused by wavelength dependency with light to be irradiated in an optical measurement method, and correctly performing a statistic test. <P>SOLUTION: The optical cerebral function imaging apparatus 1 includes: a light emission/reception part control part 4 for obtaining the respective temporal changes X<SB>n</SB>(t) of signal values A<SB>n</SB>concerning cerebral activities in N measurement parts on the cerebral surface of a subject; a general linear model generating part 31 for expressing the temporal changes X<SB>n</SB>(t) of the signal values A<SB>n</SB>with the use of general linear models Y<SB>n</SB>(t); a t-value calculating part 32 for calculating t-vales for performing the test concerning a plurality of partial regression coefficients β<SB>p</SB>; and a t-testing part 33 for testing significance of the general linear models Y<SB>n</SB>(t). The signal value A<SB>n</SB>is a voltage value ratio or absorbance. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

The present invention relates to an optical brain functional imaging apparatus that analyzes and measures temporal changes in signal values related to brain activity at a plurality of measurement sites using light, and more specifically, a signal by statistical test using a general linear model. The present invention relates to an optical brain functional imaging apparatus that analyzes and measures changes in values over time.

In recent years, in order to observe the activity state of the brain, an optical brain functional imaging apparatus has been developed that uses light for simple and non-invasive measurement. Such an optical brain functional imaging apparatus includes a light transmitting probe and a light receiving probe at set intervals (channels). As a result, in the optical brain functional imaging apparatus, near-infrared light of two different wavelengths λ ₁ and λ ₂ (for example, 780 nm and 830 nm) is applied to the brain by a light transmission probe arranged on the skull surface of the subject. In addition to irradiation, signal values A (λ ₁ ) and A (λ ₂ ) are detected based on the intensity of near-infrared light of each wavelength emitted from the brain by a light receiving probe arranged on the surface of the skull.
Here, near-infrared light of each wavelength λ ₁ and λ ₂ is transmitted through the scalp tissue and bone tissue, and oxyhemoglobin and deoxyhemoglobin have different spectral absorption spectrum characteristics from visible light to near-infrared region. Therefore, it is particularly absorbed by either oxyhemoglobin or deoxyhemoglobin in the blood. FIG. 4 is a graph showing spectral absorption coefficients of oxyhemoglobin and deoxyhemoglobin.

Therefore, in order to calculate the concentration / optical path length product [oxyHb] of oxyhemoglobin in the cerebral blood flow and the concentration / optical path length product [deoxyHb] of deoxyhemoglobin, for example, using the modified Beer Lambert rule, the relational expression (4 ) The simultaneous equations shown in (5) are created and the simultaneous equations are solved (for example, see Non-Patent Document 1). Furthermore, the concentration / optical path length product ([oxyHb] + [deoxyHb]) of total hemoglobin is calculated from the oxyhemoglobin concentration / optical path length product [oxyHb] and deoxyhemoglobin concentration / optical path length product [deoxyHb]. ing.
A (λ ₁ ) = E _O (λ ₁ ) × [oxyHb] + E _d (λ ₁ ) × [deoxyHb] (4)
A (λ ₂ ) = E _O (λ ₂ ) × [oxyHb] + E _d (λ ₂ ) × [deoxyHb] (5)
Here, E _O (λm) is an absorbance coefficient of oxyhemoglobin in light of wavelength λm, and E _d (λm) is an absorbance coefficient of deoxyhemoglobin in light of wavelength λm.

In the optical brain functional imaging device, oxyhemoglobin concentration / optical path length product [oxyHb], deoxyhemoglobin concentration / optical path length product [deoxyHb], and total hemoglobin concentration / optical path length product at the brain measurement site for the entire brain surface In order to measure ([oxyHb] + [deoxyHb]), for example, a near-infrared spectrometer (hereinafter abbreviated as NIRS) is used (see, for example, Patent Document 1).
In NIRS, a holder is used to bring a plurality of light-transmitting probes and a plurality of light-receiving probes into close contact with the surface of the subject's skull in a predetermined arrangement. As such a holder, for example, a molded holder molded into a bowl shape in accordance with the shape of the skull surface is used. The molding holder is provided with a plurality of through holes, and by inserting the light transmitting probe and the light receiving probe into the through holes, the set interval (channel) becomes constant, and the N depth from the skull surface has a specific depth. Signal values A _n (λ ₁ ), A _n (λ ₂ ) (n = 1, 2,..., N) are obtained. In general, a set interval (channel) of 30 mm is used. When the channel is 30 mm, the signal values A _n (λ ₁ ) and A _{n at} a depth of 15 mm to 20 mm from the midpoint of the channel are used. It is believed that (λ ₂ ) is obtained. That is, the position 15 mm to 20 mm deep from the surface of the skull substantially corresponds to the surface area of the brain, and the signal values A _n (λ ₁ ) and A _n (λ ₂ ) related to the brain activity at the N measurement sites on the brain surface are obtained. .

FIG. 2 is a plan view showing an example of the positional relationship between 11 light transmitting probes and 12 light receiving probes in NIRS as described above. The NIRS 11 is a hemispherical shape in which the light transmitting probes 12a to 12k and the light receiving probes 13a to 13j are arranged in a square lattice pattern so as to alternate in the row direction and the column direction. Note that near-infrared light emitted from the light-transmitting probes 12a to 12k is also detected by remote light-receiving probes 13a to 13j other than the adjacent light-receiving probes 13a to 13j. It is assumed that detection is performed only by the light receiving probes 13a to 13j. Therefore, signal values A _n (λ ₁ ) and A _n (λ ₂ ) (n = 1, 2,..., 32) at a total of 32 (= N) measurement sites are obtained.
Then, from the signal values A _n (λ ₁ ) and A _n (λ ₂ ) at a total of 32 measurement sites, a simultaneous equation is created as described above, and the concentration / optical path length product [oxyHb] of oxyhemoglobin, Deoxyhemoglobin concentration and optical path length product [deoxyHb] are calculated.

By the way, the calculated concentration / optical path length product [oxyHb] of oxyhemoglobin and deoxyhemoglobin concentration / optical path length product [deoxyHb] are information from oxyhemoglobin and deoxyhemoglobin in the bloodstream of the brain (brain cortex). And information from oxyhemoglobin and deoxyhemoglobin in other bloodstreams (for example, skin bloodstream), and these need to be distinguished.
Therefore, a statistical test method using a general linear model (GLM) has been established as a distinction method. For example, assuming a plurality of basic functions S _p (t) (p = 1, 2,..., P−1) in advance, the time variation of the obtained oxyhemoglobin concentration / optical path length product [oxyHb] and deoxy a time change of concentration-path length product of hemoglobin [deoxyHb], formula expressed by a general linear model Y _{n (t)} shown in (1), the general linear model Y basic function at _{n (t)} S _{p (t)} The coefficient (partial regression coefficient) β _{p is} fitted by the least square method, the partial regression coefficient β _p is statistically tested, and the validity of the fitting is tested to determine the product of oxyhemoglobin concentration and optical path length [ The analysis of the general linear model Y _n (t) expressing the time change of oxyHb] and the time change of deoxyhemoglobin concentration / optical path length product [deoxyHb] is performed.
Y _n (t) = β ₀ + β ₁ S ₁ (t) +. + Β _P-1 S _P-1 (t) + ε _n (1)
Here, β ₀ is a baseline value, and ε _n is a residual component (aggregation of noise components).
Then, using the results of the analysis, the brain function imaging image obtained by color mapping the concentration / optical path length product [oxyHb] of oxyhemoglobin and the deoxyhemoglobin concentration / optical path length product [deoxyHb] for each measurement site n or significant Channels (significant measurement sites n) are displayed.
JP 2006-109964 A Factors affecting the accuracy of near-infrared spectroscopy concentration calculations for focal changes in oxygenation parameters, NeuroImage 18, 865-879, 2003

However, the length of the optical path length through which near-infrared light of each wavelength λ ₁ and λ ₂ passes from the light transmitting probe 12 to the light-receiving probe 13 has wavelength dependency due to the degree of scattering of the near-infrared light. That is, even if the signal value A _n (λ _m ) is obtained by a combination of the same light transmission probe 12 and light reception probe 13 (for example, the light transmission probe 12a and the light reception probe 13a), the light of wavelength λ ₁ and the wavelength λ ₂ The length of the optical path length through which the light passes is different. Therefore, even if the simultaneous equations are created as described above to obtain the concentration / optical path length product [oxyHb] of oxyhemoglobin and the concentration / optical path length product [deoxyHb] of deoxyhemoglobin, these simultaneous equations are different. Since it is assumed that light of two types of wavelengths λ ₁ and λ ₂ has passed through the same distance, it causes crosstalk. As a result, the exact concentration / optical path length product [oxyHb] of oxyhemoglobin and deoxyhemoglobin There was a problem that the concentration / optical path length product [deoxyHb] could not be obtained.

In order to obtain signal values A _n (λ ₁ ) and A _n (λ ₂ ) (n = 1, 2,..., 32) at a total of 32 measurement sites by the NIRS 11 as described above, for example, , the light of the wavelength lambda ₁ is sending 0.15 seconds to the light-sending probe 12a, then the light of wavelength lambda ₁ so as to sending 0.15 seconds to the light-sending probe 12b, feeding the light transmitting probe 12a turn is sending the light of the wavelength lambda ₁ to the light probe 12k, Furthermore, after sequentially by sending the light of the wavelength lambda ₁ from the light transmitting probe 12a to the light transmitting probe 12k is the same way light transmitting probe 12a and by sending the light of the wavelength lambda ₂ in order until the light transmitting probe 12k from. That is, when observing the neuroimaging image for the entire brain surface of time, the time at which the light transmitting probe 12a has sending the light of the wavelength lambda _1, the time the light transmitting probe 12k was sending the light of the wavelength lambda ₂ There was a problem that the difference between was too large. This is a serious problem when the number of light transmitting probes is further increased.
Further, in the configuration of the optical brain functional imaging apparatus, the light transmitting probe 12 emits the light of wavelength λ _{1 and} the light of wavelength λ ₂ , and the light receiving probe 13 emits the light of wavelength λ _{1 and} the light of wavelength λ _2. Since it is necessary to make it detect, there existed a problem that the structure of an optical brain functional imaging apparatus became complicated and cost also increased. This is a serious problem when the number of light transmitting probes and light receiving probes is further increased.
Therefore, the present invention does not complicate the structure of the apparatus and does not increase the cost, and furthermore, it is possible to perform an accurate statistical test by eliminating the problem caused by the wavelength dependence due to the irradiated light in the optical measurement method. An object is to provide an optical brain functional imaging apparatus.

The optical brain functional imaging apparatus of the present invention made to solve the above problems comprises a plurality of light transmitting probes arranged on the surface of the subject's skull and a plurality of light receiving probes arranged on the surface of the skull. The light transmitting / receiving unit and the light transmitting probe irradiate light on the surface of the skull, and the light receiving probe is controlled to detect the intensity of light emitted from the surface of the skull. A transmitter / receiver controller that obtains time variations X _n (t) of signal values A _n (n = 1, 2,..., N) relating to brain activity at N measurement sites, and a plurality of basic functions _Sp ( t) (p = 1, 2,..., P−1) and a signal value by a general linear model (GLM) using a partial regression coefficient β _p that is a coefficient of a plurality of basic functions S _p (t). the time change _X n of a _n (t), general linear model represented by the following formula (1) A general linear modeling unit to express Le Y _{n (t),} and t-value calculating unit that calculates a t value for performing an assay for partial regression coefficient beta _p in the general linear model Y _{n (t),} was calculated an optical brain functional imaging apparatus including a t-test unit that tests the significance of the general linear model Y _n (t) based on a t-value, and the signal value _An is a voltage value represented by the following equation (2): A light-emitting unit that transmits light of one type of setting wavelength to the light-transmitting probe, and the light-transmitting / receiving-unit control unit uses the light-emitting unit to transmit the light-transmitting probe. from one type of light of predetermined wavelength by irradiating the surface of the skull, by detecting the intensity of light of one predetermined wavelength by the light receiving probe, to obtain the time change X _n of the signal value a _{n (t)} I have to.
Y _n (t) = β ₀ + β ₁ S ₁ (t) +. + Β _P−1 S _P−1 (t) + ε _n (1)
Here, β ₀ is a baseline value, and ε _n is a residual component.
A _n = V _n / V _n0 (2)
A _n = −log (V _n / V _n0 ) (3)
Here, V _n is a measurement voltage value indicating the intensity of light detected at the measurement site n, and V _n0 is a preset reference voltage value at the measurement site n.

Here, the “reference voltage value” means, for example, a voltage value set in advance according to the intensity of light to be irradiated, a measured voltage value obtained by measuring the rest of the subject in advance, or the like. .
According to the optical brain functional imaging apparatus of the present invention, the light transmission / reception unit controller irradiates the skull surface with light of one type of setting wavelength from the light transmission probe, and the intensity of light of one type of setting wavelength with the light receiving probe. It is to detect, obtain time change X _n signal values a _n of the measurement site of the n locations of the _(t), respectively. In the present invention, light other than the set wavelength is not irradiated. Therefore, simultaneous equations are not created to obtain the concentration / optical path length product [oxyHb] of oxyhemoglobin and the deoxyhemoglobin concentration / optical path length product [deoxyHb]. As a result, the occurrence of crosstalk can be eliminated, and an accurate statistical test can be performed.
The general linear modeling unit is generally linear which indicates a plurality of basic functions S _{p (t),} the equation (1) using the partial regression coefficients a coefficient of the plurality of basic functions S _{p (t)} beta _p the model (GLM), expressing the time change _X n of the signal value _{a n} (t) by the general linear model _Y n (t).
Y _n (t) = β ₀ + β ₁ S ₁ (t) +. + Β _P−1 S _P−1 (t) + ε _n (1)
That is, the general linear model Y _n (t) can be fitted with a linear sum of several basic functions S _p (t) (p = 1, 2,. It is assumed that the difference component ε _n has a normal distribution N (0, σ).

Then, when the matrix representation of generalized linear model _Y n (t) of the time change _X n signal values _{A n} of each measurement site of the formula (1) (t), the following equation (6) (or formula ( 6 ')).

Here, Y is a signal value vector, β is a partial regression coefficient vector, G is a design matrix, and ε is a residual vector.
Now, in order to perform a statistical test, an estimate of Y
And the estimated value of β
And can be written as in the following formula (7).

At this time,
Using the condition that minimizes
(Least square method).

At this time, the t value is given by:

Here, t-test is performed under the assumption (null hypothesis) of β = 0 (β _j = 0). In this case, the t value is obtained by the following equation (8).

Where c is a contrast vector, for example
C = (0,1,0,0,, 0)
C = (0,0,1,0,., 0) is obtained.
Further, the signal value A _n may be regarded as independent, the following equation.

Then, the t-test unit sets a significance level (for example, 5%). As a result of an assumption (null hypothesis) that β = 0 (β _j = 0), the t-value is set to a rejection range where the t-value is 5%. Whether or not to enter is tested with the t value obtained by equation (8). In this way
Each ingredient
Perform the test.
Then, by using the t-test results for each measurement site n, to create a signal value A _n of the time change X _{n (t)} color mapping brain function imaging image (t value map), significant channel (significance Display the measurement site n). Thereby, it is possible to accurately observe the measurement site n where the brain activity (brain change) occurred.

As described above, according to the optical brain functional imaging apparatus of the present invention, since only one type of light having a set wavelength is used, the structure of the apparatus is not complicated and the cost is not increased. Furthermore, it does not create simultaneous equations to calculate the oxyhemoglobin concentration / optical path length product [oxyHb] and deoxyhemoglobin concentration / optical path length product [deoxyHb]. Accurate statistical tests can be performed without the problems caused by dependencies. Therefore, it is possible to accurately observe the measurement site n where the brain activity (brain change) occurred.

(Means and effects for solving other problems)
In the optical brain functional imaging apparatus of the present invention, the set wavelength may be 805 nm, which is an isosbestic point between the spectral absorption coefficient of oxyhemoglobin and the spectral absorption coefficient of deoxyhemoglobin.
According to the optical brain functional imaging apparatus of the present invention, it is possible to create a brain functional imaging image in which the total hemoglobin concentration / optical path length product is color-mapped. Furthermore, it is possible to accurately observe the measurement site n in which the total hemoglobin concentration / optical path length product has changed.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, this invention is not limited to the following embodiment, It cannot be overemphasized that various aspects are included in the range which does not deviate from the meaning of this invention.

FIG. 1 is a block diagram showing a configuration of an optical brain function imaging apparatus according to an embodiment of the present invention. The optical brain function imaging apparatus 1 includes a light transmission / reception unit 11, a light emitting unit 2, a light detection unit 3, and a control unit (computer) 20 that controls the entire optical brain function imaging device 1.
FIG. 2 is a plan view illustrating an example of the light transmitting / receiving unit 11.
The light transmitting / receiving unit 11 has 11 light transmitting probes 12a to 12k and 10 light receiving probes 13a to 13j, and the light transmitting probes 12a to 12k and the light receiving probes 13a to 13j are alternately arranged in the row direction and the column direction. The hemispheres are arranged in a square lattice so that The shortest distance (channel) between the light transmitting probe 12 and the light receiving probe 13 is 30 mm. Further, the eleven light transmitting probes 12a to 12k emit near-infrared light of one kind of set wavelength (for example, 805 nm), while the ten light receiving probes 13a to 13j are one kind of light. The amount (intensity) of near infrared light having a set wavelength (for example, 805 nm) is detected.
And the light transmission / reception part 11 will be mounted | worn with a test subject's head.

The light emitting unit 2 transmits near-infrared light of one set wavelength to one light transmission probe selected from among the 11 light transmission probes 12a to 12k by a drive signal input from the computer 20. . In the present embodiment, since it is not necessary to irradiate light other than the set wavelength (for example, 805 nm), a configuration for transmitting near-infrared light of two different wavelengths as in the conventional optical brain functional imaging apparatus. Is not provided.
Light detector 3, by detecting the intensity of the near-infrared light of one setting wavelength received by the 10 light receiving probes 13a-13j, and outputs the measured voltage value V _n in the computer 20. In addition, although the near-infrared light irradiated from each light transmission probe 12a-12k is detected also in remote light reception probes 13a-13j other than the adjacent light reception probes 13a-13j, here, in order to simplify description, The detection is performed only by the adjacent light receiving probes 13a to 13j. Therefore, when the near infrared light is sending eleven all light transmitting probe 12a~12k, it is assumed that the voltage value measured _{V n} at the measurement site a total of 32 points (channel number 1 to 32) is obtained.

The computer 20 includes a CPU 21, and further includes a memory 25, a display device 23 having a monitor screen 23 a and the like, and a keyboard 22 a and a mouse 22 b which are input devices 22.
Further, the functions processed by the CPU 21 will be described in the form of blocks. The light transmission / reception unit control unit 4 that controls the light emitting unit 2 and the light detection unit 3, the general linear model creation unit 31, the t value calculation unit 32, and the t test. Part 33. Further, the memory 25 includes a signal value storage unit 51 for storing the measured time t and the signal value A _n.

Receiving unit controller 4 transmission includes a light emitting controller 42 for outputting a drive signal to the light-emitting unit 2, by receiving the measured voltage value V _n from the light detection unit 3, the signal value A _n in the signal value storing unit 51 And a light detection control unit 43 to be stored.
The light emission control unit 42 performs control to output to the light emitting unit 2 a drive signal that causes the light transmission probe 12 to transmit near-infrared light having one set wavelength. For example, first, the light transmission probe 12a transmits light of 805 nm for 0.15 seconds, and then the light transmission probe 12b transmits light of 805 nm for 0.15 seconds. A drive signal for transmitting light of 805 nm in order to the probe 12k is output to the light emitting unit 2.
Light detection control unit 43 by receiving the measured voltage value V _n from the light detection unit 3 calculates a signal value A _n using Equation (3), the signal value A _n in the signal value storing unit 51 The control to memorize is performed. For example, the measurement voltage values V ₁ and V ₇ obtained by detecting the 805 nm light transmitted from the light transmitting probe 12a by the light receiving probes 13a and 13d are received, and then the 805 nm light transmitted from the light transmitting probe 12b. the light receiving probes 13a, 13b, the measured voltage value _V 2 detected by _13e, V 3, to receive the _{V 9,} the probe receives light 805nm was sending eleven light transmitting probe 12A～12k 13a-13j The measured voltage value V _n detected in step ₁ is received. Then, to calculate the signal values A _n using Equation (3), and stores the signal value A _n in the signal value storing unit 51.
A _n = −log (V _n / V _n0 ) (3)
Here, V _n is a measurement voltage value indicating the intensity of light detected at the measurement site n, and V _n0 is a preset reference voltage value at the measurement site n.

The general linear model creation unit 31 includes a plurality of basic functions S _p (t) (p = 1, 2,..., P), a partial regression coefficient β _{p that} is a coefficient of the plurality of basic functions S _p (t), and the general linear model (GLM) was used, and the time change _X n of the signal value _{a n} (t), and performs control to represent by the formula (1) generally show a linear model _Y n (t).
Y _n (t) = β ₀ + β ₁ S ₁ (t) +. + Β _P−1 S _P−1 (t) + ε _n (1)
Here, β ₀ is a baseline value, and ε _n is a residual component (aggregation of noise components).

The t value calculation unit 32 performs control for calculating a t value for performing a test on the partial regression coefficient β _p based on the following equation (8).

Where c is a contrast vector, for example
C = (0,1,0,0,, 0)
C = (0,0,1,0,., 0) is obtained.
As a result of the assumption that β = 0 (null hypothesis) with respect to a preset significance level (set to 5%), the t-test unit 33 is a rejection area in which the t value calculated by the t value calculation unit 32 is 5%. The t value map (t mapping data) is created using the t test result for each measurement site n, and a significant channel (measurement site n with significance) is displayed. The control which performs is performed.

Next, a measurement method using the optical brain function imaging apparatus 1 will be described. FIG. 3 is a flowchart for explaining an example of a measurement method by the optical brain function imaging apparatus 1.
First, in the process of step S101, the light transmitting / receiving unit 11 is disposed on the surface of the examiner's skull.
Next, in the process of step S _< b _> 102, the light emission control unit 42 and the light detection control unit 43 output a drive signal to the light emission unit 2 and receive the measured voltage value Vn from the light detection unit 3.
Next, in the process of step S _< b _> 102, the light detection control unit 43 calculates the signal value An using Expression (3), and stores the signal value _An in the signal value storage unit 51.

Next, in the process of step S104, the general linear model creation unit 31 includes a plurality of basic functions S _p (t) (p = 1, 2,..., P−1) and a plurality of basic functions S _p (t ) By using a general linear model (GLM) using a partial regression coefficient β _p that is a coefficient of), a time change X _n (t) of the signal value An is _expressed by a general linear model Y _n (t) shown in the equation (1). It expresses with.
Next, in the process of step S105, the t value calculation unit 32 calculates a t value for performing a test on the partial regression coefficient β _p based on the equation (8).
Next, in the process of step S106, the t-test unit 33 is calculated by the t-value calculating unit 32 as a result of an assumption (null hypothesis) that β = 0 with respect to a preset significance level (set to 5%). In addition, a calculation is performed to test whether or not the t value falls within the 5% rejection range, and a t value map (t mapping data) is created using the t test result for each measurement site n, and a significant channel (significant) Display the measurement site n).
Finally, when the process of step S106 is completed, this flowchart is ended.

As described above, according to the optical brain function imaging apparatus 1, the operator can confirm the t value distribution of each measurement site n and the determination result as to whether it is significant. Also, since only one type of light having a set wavelength is used, the apparatus structure is not complicated and the cost is not increased. Furthermore, it does not create simultaneous equations to calculate the oxyhemoglobin concentration / optical path length product [oxyHb] and deoxyhemoglobin concentration / optical path length product [deoxyHb]. Accurate statistical tests can be performed without the problems caused by dependencies. Therefore, it is possible to accurately observe the measurement site n where the total hemoglobin concentration / optical path length product has changed.

(Other embodiments)
(1) In the optical brain functional imaging apparatus 1 described above, the light transmitting / receiving unit 11 having 11 light transmitting probes 12a to 12k and 10 light receiving probes 13a to 13j is shown. It is good also as a light transmission / reception part which has a light transmission probe and nine light reception probes.
(2) In the optical brain functional imaging apparatus 1 described above, the configuration in which the signal value is calculated using A _n = −log (V _n / V _n0 ) has been shown, but A _n = V _n / V _n0 is used. The signal value may be calculated.

  INDUSTRIAL APPLICABILITY The present invention can be used for an optical brain functional imaging apparatus that analyzes and measures a time change of a signal value by a statistical test using a general linear model.

It is a block diagram which shows the structure of the optical brain functional imaging apparatus which is one Embodiment of this invention. It is a top view which shows an example of a light transmission / reception part. 5 is a flowchart for explaining an example of a measurement method by the optical brain function imaging apparatus 1; It is a graph which shows the spectral absorption coefficient of oxyhemoglobin and deoxyhemoglobin.

Explanation of symbols

1: optical brain functional imaging device 2: light emitting unit 4: light transmitting / receiving unit control unit 11: light transmitting / receiving unit 12: light transmitting probe 13: light receiving probe 31: general linear model creation unit 32: t value calculation unit 33: t test unit

Claims (2)

A plurality of light transmission / reception probes arranged on the surface of the subject's skull, a light transmission / reception unit comprising a plurality of light reception probes arranged on the surface of the skull,
The light-transmitting probe irradiates light on the surface of the skull, and the light-receiving probe is controlled so as to detect the intensity of light emitted from the surface of the skull, so that N measurement sites on the brain surface of the subject can be obtained. A transmitter / receiver controller that obtains time changes X _n (t) of signal values A _n (n = 1, 2,..., N) relating to brain activity in
General linear model using a plurality of basic functions S _p (t) (p = 1, 2,..., P−1) and a partial regression coefficient β _p that is a coefficient of the plurality of basic functions S _p (t) the (GLM), the time change _X n of the signal value _{a n} (t), and the general linear modeling unit to represent the general linear model _Y n (t) represented by the following formula (1),
A t value calculation unit for calculating a t value for performing a test on the partial regression coefficient β _p in the general linear model Y _n (t);
An optical brain functional imaging apparatus comprising: a t-test unit that tests the significance of the general linear model Y _n (t) based on the calculated t-value;
The signal value _An is a voltage value ratio shown in the following formula (2) or an absorbance shown in the following formula (3).
A light emitting unit that transmits light of one type of setting wavelength to the light transmitting probe,
The light transmitting / receiving unit control unit causes the light emitting unit to irradiate the skull surface with light of one type of setting wavelength from the light transmitting probe, and causes the light receiving probe to detect the intensity of light of one type of setting wavelength, light brain function imaging apparatus, characterized in that the time change X to obtain _{n (t)} is the signal value a _n.
Y _n (t) = β ₀ + β ₁ S ₁ (t) +. + Β _P−1 S _P−1 (t) + ε _n (1)
Here, β ₀ is a baseline value, and ε _n is a residual component.
A _n = V _n / V _n0 (2)
A _n = −log (V _n / V _n0 ) (3)
Here, V _n is a measurement voltage value indicating the intensity of light detected at the measurement site n, and V _n0 is a preset reference voltage value at the measurement site n. 2. The optical brain functional imaging apparatus according to claim 1, wherein the set wavelength is 805 nm, which is an isosbestic point between a spectral absorption coefficient of oxyhemoglobin and a spectral absorption coefficient of deoxyhemoglobin.