JP4559386B2 - Biological light measurement device - Google Patents

Description

  The present invention relates to an apparatus for measuring metabolites inside a living body using light.

In living body measurement using light, an apparatus for measuring a living body function using visible to near-infrared light is disclosed in, for example, Japanese Patent Application Laid-Open No. 57-115232 or Japanese Patent Application Laid-Open No. 63-275323. . Further, a proposal (optical topography) relating to an image measurement technique for brain function by applying this measurement principle is disclosed in Japanese Patent Laid-Open No. 9-98972.
These use optical waveguide means represented by an optical fiber or the like, and irradiate light on a living body and scatter light within the living body at a position away from several mm to several centimeters (hereinafter abbreviated as living body scattered light). Condensation measurement. Based on the measured intensity of the scattered light from the living body, the concentration of the light-absorbing substance in the living body or a value corresponding to the concentration, such as oxyhemoglobin and reduced hemoglobin, is obtained. When obtaining the light-absorbing substance concentration or a value corresponding to the concentration, the light-absorbing characteristic of the target light-absorbing substance corresponding to the wavelength of the irradiated light is used. Generally, when measuring a deep part of a living body, light having a wavelength within a range of 650 nm to 1300 nm having high biological permeability is used.

JP 57-115232 A JP-A 63-275323 JP-A-9-98972

  The biological light measurement has means for irradiating light (hereinafter abbreviated as light irradiating means) and means for collecting and detecting light passing through the living body (hereinafter abbreviated as light condensing detection means). As these light irradiation means and light condensing detection means, optical waveguides represented by optical fibers or optical fiber bundles are often used. One set of optical waveguides for light irradiation and light condensing detection is a minimum unit (hereinafter abbreviated as a light irradiation condensing pair) representing one measurement position. An apparatus for measuring a living body image by setting a plurality of the minimum units is disclosed in Japanese Patent Laid-Open No. 9-98972. Here, the distance between the irradiation position of the light irradiation condensing pair and the condensing position (hereinafter, abbreviated as the distance between the light irradiation condensing pair) varies depending on the width or depth of the region to be measured.

  Therefore, in Japanese Patent Laid-Open No. 9-98972, the optical waveguide for light irradiation and the optical waveguide for light collection are alternately arranged on the apex of the square lattice so that the distance between the respective light irradiation and condensing pairs becomes equal. The arrangement | positioning form to arrange | position is disclosed. If this arrangement is used, one optical waveguide is shared by a plurality of light irradiation and condensing pairs, so that image measurement can be performed with a small number of optical waveguides. Therefore, the optical waveguide can be attached to the living body in a short time.

  However, this arrangement can be applied to a narrow area of a living body that can be approximated by the plane of the living body (for example, about 15 cm square in the case of the head), but it can be applied to a wide area that can be approximated only by a spherical surface. Application is difficult. However, actually, measurement of a larger area (for example, the entire brain) is required by using the technique disclosed in Japanese Patent Laid-Open No. 9-98972. This is because the brain shares various functions for each location, and the local measurement cannot observe the correlation for each location. Therefore, the demand to expand the measurement area, for example, to be able to measure the entire brain must be satisfied in practice.

  In order to satisfy this requirement, that is, an optical waveguide has to be arranged over the entire head, and the following practical problems arise.

(1) Optical waveguide arrangement:
As described above, in the square lattice arrangement form, it is difficult to uniformly fill the head having a shape close to a hemisphere.

(2) Number of optical waveguides:
Since the number of optical waveguides is increased, it takes a set time and the burden on the operator and the subject increases.

  Therefore, the present invention has been made paying attention to the above-mentioned points, and it is possible to arrange an optical waveguide with almost no gap with respect to the subject's head, and to reduce the setting time of the optical waveguide significantly. An object of the present invention is to provide a measurement device and a biological light measurement fixture.

  Solving the above problems is indispensable for expanding the measurement area of biological light measurement.

  In the present invention, in order to solve the above problem (1), the following three means are provided.

  1) The entire head of the subject is regarded as a set of multiple areas. Each region has a shape that can be composed of the same square lattice. The optical waveguide is arranged on each square lattice vertex. The problem with this means is that a gap is generated in each area. If this gap cannot be ignored, the entire area is measured by filling the gap with a square lattice.

  2) A rectangular lattice having substantially the same side is filled on the head with as little gap as possible, and an optical waveguide is placed on the vertex of the lattice. Also in this case, it is difficult to completely fill the entire head with a quadrangular lattice, and a gap is generated. Therefore, the light irradiation / condensing pair is arranged so as to fill the gap, and the entire region is measured. Further, for example, since it is difficult to make the length of one side of a quadrangular lattice the same, the distance between the incident and condensing optical waveguides varies. Accordingly, since the signals cannot be evaluated identically, correction is performed using a correction coefficient corresponding to the distance given in advance. However, when the difference in one side length is too large, correction is difficult, and thus it is necessary to provide an allowable range for the difference in length of one side. In addition, in common with 1) and 2), it is difficult to adapt to the head shape of each individual. Therefore, a plurality of arrangement forms are prepared and the most suitable one is used for measurement.

3) If the entire head is approximated to a hemisphere, this problem will result in the problem of filling the hemisphere with geometric figures. As an example of the solution, there is a combination of a regular hexagon and a regular pentagon. For example, a C ₆₀ molecular structure called florene and a soccer ball are typical examples. Similar to 1) and 2), if a condensing optical waveguide is arranged on the apexes of a regular hexagon and a regular pentagon, the same pattern (here, two types of patterns) can be formed on the head without a gap. ) Can arrange the optical waveguide. Further, a plurality of optical waveguides for light irradiation are arranged at the center of each regular hexagon and regular pentagon. This arrangement can solve the above problem (1). In addition, by making the positions of a plurality of optical waveguides for light irradiation arranged at the center variable, it becomes possible to keep the distance between the optical waveguides for light irradiation and light collection constant. Furthermore, it is possible to cope with various head sizes depending on the insertion amount of the optical waveguide.

The above problem (2) is an important problem that must be solved when the head is a measurement target, especially because the hair becomes an obstacle. Accordingly, two means for solving this problem are provided.
1) The optical waveguide is brought into contact with the skin while vibrating.
2) Avoiding hair by blowing air from around or inside the optical waveguide and contacting the optical waveguide.

  As described above, the present invention provides a light irradiating means for irradiating light to the object to be inspected and a light condensing detecting means for collecting and detecting the light irradiated from the light irradiating means and propagated through the object to be inspected. In the biological optical measurement device that is configured to measure the metabolite in the subject based on the signal detected by the light collection detection means, the subject to be inspected is divided into a plurality of regions, A biological light measuring device, wherein the light irradiation means and the light collecting detection means are alternately arranged on the apex of the square lattice. provide.

  Further, the present invention provides a light irradiating means for irradiating light to the object to be inspected, and a light collecting detecting means for collecting and detecting light irradiated from the light irradiating means and propagated through the object to be inspected on the object to be inspected. In a biological light measuring device that is mounted and configured to measure a metabolite in a body to be inspected based on a signal detected by the light collection detecting means, the body to be inspected is a region that combines a triangular and a quadrangular lattice. There is provided a living body light measuring device characterized in that it is partitioned and arranged so that the light irradiating means and the light collecting and detecting means are on the triangular and quadrangular lattice vertices.

  Further, the present invention provides a light irradiating means for irradiating light to the object to be inspected and a light collecting detecting means for collecting and detecting light irradiated from the light irradiating means and propagated through the object to be inspected on the object to be inspected. In the living body optical measurement device that is mounted and configured to measure a metabolite in the subject based on the signal detected by the light collection detection means, the region in which the subject is composed of pentagonal and hexagonal lattices A living body light measuring device comprising: a light irradiating means and a light condensing detecting means arranged in a pair on the vertexes of the pentagonal and hexagonal lattices and inside the lattice. provide.

  Further, the present invention provides a light irradiating means for irradiating light to the object to be inspected, and a light collecting detecting means for collecting and detecting light irradiated from the light irradiating means and propagated through the object to be inspected on the object to be inspected. In the living body optical measurement device that is mounted and configured to measure a metabolite in the subject based on the signal detected by the light collection detection means, the region in which the subject is composed of pentagonal and hexagonal lattices A living body light measuring device comprising: a light irradiating means and a light condensing detecting means arranged in a pair on the vertexes of the pentagonal and hexagonal lattices and inside the lattice. provide.

  Further, the present invention provides the light irradiation means and the light condensing detection means in the above-described configuration, wherein an air flow is generated by the air intake / exhaust means in a region including the light irradiation means and the light condensing detection means on the object to be inspected. A living body light measuring device is provided which is configured so as to be in contact with an object to be inspected.

  Furthermore, the present invention holds an irradiation optical waveguide that irradiates light to a subject to be measured for an internal metabolite, and a condensing optical waveguide that condenses light propagated through the subject, A biological light measurement fixture for mounting on an object to be inspected, wherein the object to be inspected is divided into a plurality of regions, and each of the regions is partitioned into a plurality of square lattices to collect the irradiation optical waveguide and the optical waveguide. There is provided a biological light measurement fixture characterized by being arranged so that optical waveguides for light are alternately placed on the apexes of the square lattice.

  Furthermore, the present invention holds an irradiation optical waveguide for irradiating light to a subject to be measured for an internal metabolite and a condensing optical waveguide for condensing the light propagated through the subject. An optical measurement fixture for mounting on an object to be inspected, wherein the object to be inspected is divided into a region combining triangular and quadrangular lattices, and an irradiation optical waveguide and a condensing optical waveguide are 3 Provided is a biological optical measurement fixture characterized by being arranged so as to be on the apexes of square and quadrangular lattices.

  Furthermore, the present invention holds an irradiation optical waveguide for irradiating light to a subject to be measured for an internal metabolite and a condensing optical waveguide for condensing the light propagated through the subject. An optical measurement fixture for mounting on an object to be inspected, wherein the object to be inspected is divided into a region composed of pentagonal and hexagonal lattices, on the vertexes of the pentagonal and hexagonal lattices and inside the lattice In addition, a biological light measurement fixture is provided in which the irradiation optical waveguide and the condensing optical waveguide are arranged and configured in pairs.

  As described above, according to the present invention, the optical waveguide for measuring biological light can be arranged with almost no gap over the entire head of the subject, and the fixing for measuring biological light can greatly reduce the setting time of the optical waveguide. A tool and a biological light measurement device can be realized.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Example 1
FIG. 1 shows an optical waveguide arrangement according to a first embodiment of the present invention. In this embodiment, an arrangement example is shown in which an optical waveguide represented by an optical fiber or the like is arranged at the apex of a square lattice. The feature of this embodiment is that the head surface is regarded as a set of a plurality of regions, and has an arrangement form in which each region is filled with a square lattice having the same one side length.

  Reference numeral 1-1 denotes a subject, and reference numeral 1-2 schematically illustrates an optical waveguide fixture for fixing the optical waveguide. In this embodiment, the head is divided from region 1 to region 5 as shown in the figure. Each region was divided into regions that can be regarded as a flat surface so that it can be composed of the same square lattice with one side length. Of course, since this division changes for each subject, there are several types of division methods. For example, anatomical division methods such as forehead, parietal region, temporal region x2, and occipital region, and division for each functional area of the brain (motor sensory area, association area, visual area, auditory language area, etc.) There is also a way to go. This embodiment will be described with reference to the five divided areas shown in the figure.

  As shown in FIG. 1, irradiation and condensing optical waveguides are alternately arranged on a plurality of square lattice vertices so as to cover each region. Here, 1-3 light irradiation optical waveguides (indicated by white circles in the figure) and 1-4 condensing optical waveguides (indicated by black circles in the figure) are described only in region 1. In addition, the light irradiating optical waveguides and the condensing optical waveguides are alternately arranged on the vertices of the square lattice in other regions. Each square lattice has the same one side length, and when the cerebral cortex is to be measured, one side length of the square lattice is set to a value between 10 mm and 50 mm. A typical length is 30 mm.

  As shown in FIG. 1, in the optical waveguide arrangement based on the present embodiment, a gap is generated between each region in a portion having a high curvature. In order to fill this gap, as shown by 1-5, the light irradiating and condensing optical waveguides may be set on one or a plurality of square lattice vertices.

  Further, in this embodiment, since the arrangement form changes depending on the head shape or the head size, a plurality of types of optical waveguide fixtures having different arrangement forms are prepared, and the optical waveguide fixture most suitable for the subject is prepared. Is used for measurement.

(Example 2)
FIG. 2 shows an optical waveguide arrangement according to the second embodiment of the present invention. In this embodiment, an arrangement example is shown in which an optical waveguide represented by an optical fiber or the like is arranged at the apex of a quadrangle. The feature of this embodiment is that the head surface is filled with quadrangles so as to have as little gap as possible, and the light irradiating optical waveguides and the condensing optical waveguides are alternately arranged on the apexes of the respective quadrangles. It is in having.

  Reference numeral 2-1 denotes a subject, and 2-2 schematically illustrates an optical waveguide fixture for fixing the optical waveguide. In this embodiment, as shown in FIG. 2, the entire head is divided so as to be filled with quadrangles, and an optical waveguide is arranged on the apex of each quadrangle. Of course, since this division changes for each subject, there are a plurality of types of division methods.

  As shown in FIG. 2, incident and condensing optical waveguides are alternately arranged on a plurality of quadrangular vertices so as to cover each region. The light irradiating optical waveguide is indicated by white circles as indicated by 2-3 in the figure, and the condensing optical waveguide is indicated by black circles as indicated by 2-4 in the figure. The length of one side of each quadrangle is within an error of ± 5 mm so that the light transmission depth can be regarded as the same.

  Even if the present embodiment is used, a gap is generated between the regions in a portion having a high curvature. In order to fill this gap, a light irradiation / condensation pair of 2-5-1 and 2-5-2 and a light irradiation / condensation pair of 2-6-1 and 2-6-2 are provided and interpolated.

  Further, in this embodiment, since the arrangement form changes depending on the head shape or the head size, a plurality of types of optical waveguide fixtures having different arrangement forms are prepared, and the optical waveguide fixture most suitable for the subject is prepared. Is used for measurement.

(Example 3)
FIG. 3 shows an optical waveguide arrangement according to a third embodiment of the present invention. In this embodiment, a pentagon and a hexagon are combined, and an arrangement example in which an optical waveguide represented by an optical fiber is arranged at each vertex is shown. The feature of this embodiment, the head assuming a spherical, C ₆₀ or similar to the fluorene as represented by C _70, fill the pentagonal and hexagonal in has been the head assumed the spherical. The feature of this arrangement form is that it has an arrangement form in which an optical waveguide for light irradiation or an optical waveguide for condensing is arranged on the apex of each pentagon and hexagon.

Reference numeral 3-1 is a subject, and 3-2 is a schematic drawing of an optical waveguide fixture for fixing the optical waveguide. In this embodiment, as shown in FIG. 3, the entire head is divided so as to be filled with pentagons and hexagons, and an optical waveguide is arranged on the apex of each pentagon. The combination of pentagon and hexagon shown in the present embodiment is the same as Floren C ₆₀ and soccer ball. If this combination is, for example, Floren C ₇₀ , it is close to an elliptical sphere, and is suitable for the measurement of Western human heads.

  As shown in FIG. 3, the number of optical waveguides is added to the number of vertices of each polygon in the pentagon and hexagon. In this embodiment, a condensing optical waveguide is set on the vertices of each polygon as indicated by 3-3-1 and 3-4-1. In addition, as shown by 3-3-2 and 3-4-2, the same number of optical waveguides for light irradiation as the number of vertices are set inside each polygon. Further, in order to measure the center position of each polygon, a pair of optical waveguides (light irradiation / condensing pair) indicated by a light irradiation optical waveguide 3-3-3 and a light collecting optical waveguide 3-3-4. Set. Although not explicitly shown in the figure, the same is also arranged at the vertices and polygons of other pentagons and hexagons.

  Here, contrary to the above setting mode, the light irradiation optical waveguide may be set on the apex, and the condensing optical waveguide may be set inside the polygon. However, since the optical waveguide for light irradiation 3-3-3 for measuring the center of the polygon is close to the optical waveguide set inside, the optical waveguide set inside the polygon is for light irradiation. Is desirable. The reason for this is that if the condensing optical waveguide is arranged inside the polygon, the light emitted from the light irradiation optical waveguide 3-3-3 for measuring the center of the polygon is arranged inside the polygon. It will strongly enter the condensing optical waveguide. Therefore, even if the light irradiation position separation / measurement means using the frequency encoding method is used, noise is significantly increased when the condensing optical waveguide is arranged inside the polygon. However, this is not the case when the time-sharing measurement method does not perform simultaneous measurement of multiple channels.

  When this embodiment is used, one side length of the pentagon or hexagon is determined by the head diameter, so that the same arrangement is maintained by changing the distance from the optical waveguide fixture 3-2 to the scalp. It becomes possible to respond. At this time, by changing the radius of the circle in which the light irradiation optical waveguide 3-3-2 inside the polygon is arranged, the distance between the light irradiation optical waveguide and the light collecting optical waveguide is constant (for example, which test object is to be measured). 30 mm). Therefore, unlike the methods of Example 1 and Example 2, it is possible to handle a plurality of subjects with one type of arrangement. However, the number of optical waveguides to be set is increased as compared with the first and second embodiments. In that case, it is necessary to estimate the weight of the optical waveguide applied to the subject. As the optical waveguide to be set, for example, when a fluorine-added plastic fiber having a high transmittance in the near infrared region is used, the number of 200 is about 300 g, which is not a big problem.

Example 4
FIG. 4 shows details of the optical waveguide fixture according to the present invention. This figure shows a state where the subject 4-1 is wearing the optical waveguide fixture 4-2. The optical waveguide fixture 4-2 includes a multi-channel optical waveguide connector 4-6, an air supply device 4-10 represented by a compressor, an air supply tube 4-11, and an exhaust tube (hole) 4-12. Have.

  In FIG. 4, a plurality of broken lines shown inside the optical waveguide fixture 4-2 represent the light irradiation optical waveguide 4-13 or the condensing optical waveguide 4-5.

  Further, in the drawing, a plurality of white circles shown inside the optical waveguide fixture 4-2 are optical waveguide insertion holes 4-3 for light irradiation, and a plurality of white circles are shown inside the optical waveguide fixture 4-2. The black circle mark is the condensing optical waveguide insertion hole 4-4.

  The optical waveguide fixture 4-2 has a double structure, and the optical waveguide insertion hole is open on the head (inside) of the subject 4-1, and the optical waveguide is formed on the outer side and the inner side. It is wired between.

  Although seven (pieces) of the light irradiation optical waveguide, the light collecting optical waveguide, the light irradiation optical waveguide insertion hole, and the light collecting optical waveguide insertion hole are shown, for example, In the case of such an optical waveguide arrangement, there are actually about 200 optical waveguides and optical waveguide insertion holes in total. Here, only a part is shown for the sake of simplicity, and the others are omitted.

  The light irradiating the head of the subject 4-1 is emitted from the biological light measuring device 4-8, and the multichannel optical waveguide 4-7, the multichannel optical waveguide connector 4-6, and the optical waveguide for light irradiation 4-13. To reach the subject's head. The light collected from the head of the subject 4-1 passes through the condensing optical waveguide 4-5, the multichannel optical waveguide connector 4-6, and the multichannel optical waveguide 4-7. 8 is detected.

  From the optical waveguide fixture 4-2, a total of about 200 light irradiation optical waveguides 4-13 and condensing optical waveguides 4-5 come out. If these are directly wired to the biological light measurement device 4-8, the subject under test 4-1 and the biological light measurement device 4-8 cannot be separated. In such a situation, when an inconvenient situation occurs during measurement, the subject cannot move urgently, which is a problem in terms of safety. Therefore, the multi-channel optical waveguide connector 4-6 is provided between the optical waveguide fixture 4-2 and the biological light measuring device 4-8, thereby enabling free attachment / detachment.

  Further, air flows into the double structure of the optical waveguide fixture by the air supply device 4-10 connected to the optical waveguide fixture, and the hair of the subject's head is scraped off. Since the hair of the subject's head affects the setting time of the optical waveguide fixture, this hair scraping by the air flow can further reduce the setting time. Here, an air intake device represented by a vacuum pump may be used as the air supply device 4-10. In this case, the roles of the air supply pipe 4-11 and the exhaust pipe (hole) are reversed.

  FIG. 5 shows a joint portion of the multichannel optical waveguide connector 4-6. In the optical waveguide side multichannel optical waveguide connector case 5-1, the light irradiation optical waveguide 4-13 and the condensing optical waveguide 4-5 shown in FIG. 4 are representatively shown as an optical waveguide 5-2. As shown in FIG. Further, in the biological light measurement side multi-channel optical waveguide connector case 5-3, the optical waveguide from the biological optical measurement device 4-8 shown in FIG. 4 is representatively shown by the optical waveguide 5-4. Has been placed.

  In order to join the optical waveguide from the optical waveguide fixture 4-2 and the optical waveguide from the biological light measuring device 4-8, the retaining hole 5-5 and the retaining hole 5-6 are tightened with screws and nuts. As a joining method, there are other methods such as using a magnet or using a pin. For example, a multi-core connector for electric wires may be used. Moreover, since each optical waveguide from the optical waveguide fixture 4-2 and each optical waveguide from the biological light measurement device 4-8 should not be changed in combination with each other, for example, for conventional electric wires As in the case of a multi-core connector, there is no problem if the connector cases are made uneven.

  Furthermore, in the case of the biological light measurement device, the intensity of the irradiation light from the biological light measurement device is often about 1 million times stronger than the intensity of the collected light from the subject. Accordingly, the multi-channel optical waveguide connector that connects only the light irradiating optical waveguide to the optical waveguide fixture 4-2 and the multi-channel optical waveguide connector that connects only the condensing optical waveguide are arranged separately. Is preferable. As a result, it is possible to prevent the irradiation light from leaking into the light that is collected and detected and being superimposed as noise.

  The hemoglobin concentration accompanying the brain functional activity is obtained by subjecting the measurement signal at each position measured using the fixture according to the present invention described in the above embodiments to a spatial interpolation process represented by a spline function. A distribution image (frontal region, parietal region, occipital region, temporal region) distribution image over the entire brain surface of the change and its temporal change image (moving image) are displayed on the display device. When displaying, each part may be divided and displayed, or images of each part may be interpolated and connected to be displayed as one two-dimensional or three-dimensional image. When displaying as a three-dimensional image pasted on the surface of an anatomical image as represented by MRI, the opposite surface becomes a blind spot and cannot be seen. Present an image at the same time, or simultaneously present a position indication graphic such as a cursor on the display screen, and try to rotate the 3D image of hemoglobin concentration change to follow the movement of this position indication graphic Is required. Of course, an operation key such as an arrow key or a joystick provided on the keyboard may be substituted. An example of an image of local hemoglobin concentration change is disclosed in “A. Maki et al,“ Spatial and temporal analysis of human motor activity using noninvasive NIR topography ”, Medical Physics, volume 22 no.12, December 1995”. However, an image of hemoglobin concentration change over the entire brain can be realized by the present invention. This display makes it possible to visualize the relationship between a plurality of parts of the brain for the first time.

The figure which shows the 1st Example by this invention. The figure which shows the 2nd Example by this invention. The figure which shows the 3rd Example by this invention. The figure which shows the 4th Example by this invention. The figure which shows the junction part of the multichannel optical waveguide connector in FIG.

Explanation of symbols

1-1: Subject, 1-2: Optical waveguide fixture, 1-3: Optical waveguide for light irradiation, 1-4: Optical waveguide for condensing, 1-5: Square lattice, 2-1: Subject 2-2: optical waveguide fixture, 2-3: optical waveguide for light irradiation, 2-4: optical waveguide for light collection, 2-5-1: optical waveguide for light irradiation, 2-5-2: collection Optical waveguide for light, 2-6-1: Optical waveguide for light irradiation, 2-6-2 Condensing optical waveguide, 3-1: Subject, 3-2: Optical waveguide fixture, 3-3-1 : Optical waveguide for condensing, 3-2-2: Optical waveguide for light irradiation, 3-3-3: Optical waveguide for light irradiation, 3-3-3: Optical waveguide for condensing, 3-4-1: Collection Optical waveguide for light, 3-4-2: Optical waveguide for light irradiation, 4-1: Subject, 4-2: Optical waveguide fixture, 4-3: Hole for inserting optical waveguide for light irradiation, 4-4 : Condensing optical waveguide insertion hole, 4-5: Condensing optical waveguide, 4-6: Multiple Channel optical waveguide connector, 4-7: multi-channel optical waveguide, 4-8: biological light measurement device, 4-10: air supply or intake device, 4-11: air supply tube, 4-12: exhaust tube (hole) 4-13: Optical waveguide for light irradiation, 5-1: Optical channel side multi-channel optical waveguide connector case, 5-2: Optical waveguide, 5-3: Biological optical measurement side multi-channel optical waveguide connector case, 5-4 : Optical waveguide, 5-5: Fastening hole, 5-6: Fastening hole.

Claims (3)

Holds multiple light-irradiating optical waveguides that irradiate light to the object under test whose concentration or change in concentration of internal metabolites is to be measured, and multiple light-collecting optical waveguides that condense light that has propagated through the object. A fixture to perform,
A connector to which the plurality of light irradiation optical waveguides and the plurality of light collecting optical waveguides are connected together ,
The distance between the first light irradiation optical waveguide and the second light irradiation optical waveguide disposed adjacent to the first light irradiation optical waveguide in the plurality of light irradiation optical waveguides is the first light. A living body characterized by being closer to the distance between the irradiation optical waveguide and the first light collecting optical waveguide capable of collecting at least the light irradiated from the first light irradiation optical waveguide and passed through the object to be inspected Optical measuring device. The plurality of light irradiation optical waveguides and the plurality of light collecting optical waveguides are separated and wired.
The living body light measuring device according to claim 1 characterized by things. A plurality of light irradiation means for irradiating light to the head of the object to be inspected;
A plurality of light collection detecting means for collecting the light irradiated from the light irradiation means through the inspection object; and
A fixture for holding the plurality of light irradiation means and the plurality of light condensing means,
The distance between the first light irradiation means and the second light irradiation means arranged adjacent to the first light irradiation means in the plurality of light irradiation means is the first light irradiation means and the first light. A living body light measurement apparatus characterized by being closer than a distance from a first light collection detecting means capable of collecting at least light irradiated from an irradiation means and having passed through the object to be inspected.

Images