JP4699213B2 - Probe device for biological light measurement device - Google Patents

Description

  The present invention relates to a probe device for a biological light measurement apparatus that is attached to a subject for irradiation and reception of inspection light for biological light measurement.

In a conventional probe device for a biological light measurement device disclosed in, for example, Japanese Patent Application Laid-Open No. 2001-286449, a plurality of optical fiber probes are arranged in a lattice shape on a shell portion. A belt is connected to the two end portions of the shell portion via a string, and the shell portion is attached to, for example, the head by hanging the belt on the chin. The shell portion is made of soft rubber such as silicon rubber so as to follow the shape of the head portion.
However, in such a conventional probe device for a biological optical measurement device, if the fastener of a belt or string is strong, the shell portion is distorted, the position of some optical fiber probes may be displaced, There was a risk that the contact state would vary. Also, if you try to wear multiple shells to measure multiple locations at the same time, it will take time and effort to properly place each shell on the desired position on your head. There was a problem that.
An object of the present invention is to solve the above-described problems, and it is easy to mount on the subject, and the positional deviation of the optical fiber probe at the time of mounting and the variation in the state of close contact of the subject with the examination unit vary. It is providing the probe apparatus for biological light measuring devices which can prevent.

  The principle of the present invention is that a living body optical measuring device probe device has a plurality of optical fiber probe mounting portions and a non-stretchable member that is applied to a test portion of a subject, and this non-stretchable member is a conventional string and belt. The above-mentioned object is achieved by constituting the combination of two members, ie, a stretchable member that is pressed against the inspection portion with a substantially uniform force from the upper side.

It is a perspective view which shows a mode when the 1st Example of the probe apparatus for biological light measuring devices of this invention is mounted | worn with the head of a subject. It is the top view which looked at the optical fiber probe mounting part 3a provided on the holder 3 of FIG. 1 from upper direction. FIG. 3 is a cross-sectional view taken along line III-III in FIG. 2. It is a perspective view which shows a mode when the 2nd Example of the probe apparatus for biological light measuring devices of this invention is mounted | worn with the head of a subject. It is a perspective view of 3rd Example of the probe apparatus for biological light measuring devices of this invention.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

1 is a perspective view showing a probe device for a biological light measurement device according to a first embodiment of the present invention. In the drawing, the head 1 of the subject is covered with a cap-like base 1 (a bowl-like shape with the bottom removed). The base 1 is made of a material having a predetermined stretchability, for example, a jersey cloth. A tightening rubber 2 for reliably preventing the base 1 from coming off the head is provided at the peripheral portion on the large diameter side of the base 1 in place of the conventional string and belt.
A plate-like holder 3 is attached to the inner peripheral surface of the base 1. The holder 3 is provided with a plurality of probe mounting portions 3a. The probe mounting portions 3a are arranged in a grid pattern at intervals. The probe mounting portion 3 a protrudes outside the base 1 through the base hole 1 a provided in the base 1.
The holder 3 is composed of a member that keeps the distance between the probe mounting portions 3 a with respect to the expansion and contraction of the base 1. That is, the holder 3 is made of a material having rigidity that does not follow and expand even when the base 1 expands and contracts, for example, plastic, ceramic, metal, and the like.
In a state in which the base 1 is mounted on the head of the subject, the holder 3 is pressed against the head by an appropriate force that the base 1 tends to shrink.
An optical fiber probe 4 is attached to each probe attachment portion 3a. These optical fiber probes 4 include a plurality of irradiation probes that irradiate the subject with inspection light for measuring biological light, and a plurality of light receiving probes that receive the inspection light returning from the subject. These optical fiber probes 4 constitute a probe group 5. An alignment mark 15 is provided on the side surface of the base 1 for alignment with a reference position of a subject to be mounted, for example, a temple.
2 is a plan view showing each probe mounting portion 3a of FIG. 1, and FIG. 3 is a cross-sectional view taken along line III-III of FIG. 2 shows a state in which the optical fiber probe 4 is removed, and FIG. 3 shows a state in which the optical fiber probe 4 is attached.
In these drawings, the base 1 is provided with a plurality of base holes 1a through which the probe mounting portion 3a passes. Each probe mounting portion 3a is provided with a probe insertion hole 3b having a circular cross section and a plurality of (here, three) pin screw holes 3c. The probe insertion hole 3b penetrates the probe mounting portion 3a. The pin screw holes 3c are arranged at equal intervals along the circumferential direction of the probe insertion hole 3b and extend in a direction orthogonal to the probe insertion hole 3b.
Each optical fiber probe 4 has an optical fiber 6 that guides inspection light, and a cylindrical probe holder 7 that is attached to the tip of the optical fiber 6 and inserted into the probe insertion hole 3b. A plurality of positioning grooves 7a are provided on the outer periphery of the probe holder 7 at intervals from each other in the length direction of the probe insertion hole 3b (vertical direction in FIG. 3). Each positioning groove 7 a is continuously provided over the entire circumference of the probe body 7.
A screw pin 8 is screwed into each pin screw hole 3c. The screw pin 8 has a first end located within the probe mounting portion 3a and a second end protruding outside the probe mounting portion 3a. The peripheral edge of the base hole 1 a of the base 1 is sandwiched between the holder 3 and the second end of the screw pin 8. Thus, the screw pin 8 has a function of preventing the probe mounting portion 3a from coming off from the base hole 1a and preventing the holder 3 from coming off from the base 1 in cooperation with the outer surface of the holder 3. Yes.
An axial vertical hole 8 a is provided on the end surface of the screw pin 8 on the first end side. A compression spring 9 and a positioning ball 10 are inserted into the vertical hole 8a. The positioning ball 10 protrudes from the vertical hole 8 a and is pressed against the positioning groove 7 a by the spring force of the compression spring 9. Thereby, positioning with respect to the probe insertion groove | channel 3b of the probe holding body 7 is performed. In addition, the positioning ball 10 has its opening narrowed so that it does not fall out of the vertical hole 8a even when the probe holder 7 is removed from the probe insertion hole 3b. The attaching / detaching mechanism of the optical fiber probe 4 includes a pin screw hole 3c, a screw pin 8, a compression spring 9, a positioning ball 10, and a positioning groove 7a.
Next, the case where the base 1 and the holder 3 are each comprised separately regarding fixation of the holder 3 is demonstrated. Base holes 1a through which the probe mounting portion 3a passes are provided in the base 1 at two-dimensional equal intervals. The two-dimensional equal interval width is set equal to the width between the probes. A hole may be arbitrarily formed in the base 1. And the probe mounting part 3a is penetrated to the hole, and the holder 3 is fixed from the inner side of the base 1. Since the holder 3 is sandwiched between the base 1 and the head at the time of mounting, it can be fixed by the pressure between the head and the base 1.
A case where the base 1 and the holder 3 are integrally formed will be described. As described above, the base 1 is provided with the base hole 1a through which the probe mounting portion 3a passes. The probe mounting portion 3a is aligned with the base hole 1a, and the holder 3 is glued, sewn and removed from the inside or outside of the base 1. It is attached with fasteners that can be used.
In the probe device in which the holder 3 is fixed from the inside of the base 1, the holder 3 directly touches the head, so that the holder 3 is provided with a cushion material made of gel or the like in order to reduce pressure on the head. You may let them. Further, the shape of the holder 3 may be determined in accordance with the shape of the head corresponding to the measurement site.
Next, a procedure for attaching the subject to the inspection unit of the subject with the probe device for biological light measurement device will be described. First, the base 1 is put on the head so that the holder 3 is positioned on the measurement part of the head of the subject. In FIG. 1, the case where the holder 3 is located in the forehead is shown. At this time, the optical fiber probe 4 may be mounted on the probe mounting portion 3a after being mounted on the probe mounting portion 3a in advance, as shown in the figure.
In any case, when the optical fiber probe 4 is inserted into the probe insertion hole 3b, the positioning ball 10 is pressed by the outer peripheral surface of the probe holder 7. As a result, the positioning ball 10 is displaced into the vertical hole 8 a against the compression spring 9. When the optical fiber probe 4 is inserted to a position where the positioning groove 7 a faces the vertical hole 8 a, the positioning ball 10 is pushed into the positioning groove 7 a by the force of the compression spring 9. As a result, the optical fiber probe 4 is positioned and mounted on the probe mounting portion 3a.
Thus, after the probe device for a biological light measurement device is mounted on the measurement portion of the subject's head, the inspection light is irradiated onto the subject's head via the irradiation optical fiber. The inspection light returning from the head of the subject is received by a light receiving optical fiber and sent to a biological light measuring device main body (not shown). In the living body light measuring device main body, physiological changes in the living body are measured from the inspection light transmitted through the light receiving optical fiber.
According to such a probe device for a biological light measurement device, since the base 1 is made of a stretchable material, the base 1 extends evenly when the base 1 is mounted on the head of the subject. In addition, no local force is applied to the holder 3, and the holder 3 can be brought into close contact with the head with a uniform force. Further, since the holder 3 keeps the distance between the probe mounting portions 3a with respect to the expansion and contraction of the base 1, it is possible to prevent the optical fiber probe 4 from being displaced.
In addition, since the positioning groove 7a is provided in the probe holder 7 and the positioning ball 10 is pressed against the positioning groove 7a, the probe holder 7 is positioned with respect to the probe insertion hole 3b. It is easy and the optical fiber probe 4 can be easily attached to and detached from the probe mounting portion 3a while the holder 3 is attached to the base 1.
Furthermore, since the plurality of positioning grooves 7a are provided in the probe holder 7, fine position adjustment of the optical fiber probe 4 can be easily performed.
Furthermore, since the screw pin 8 into which the compression spring 9 and the positioning ball 10 are inserted also serves as a stopper for preventing the holder 3 from coming off the base 1, the number of parts can be reduced and the configuration can be simplified.

FIG. 4 is a perspective view showing a probe device for a biological light measurement device according to a second embodiment of the present invention. In the first embodiment, one holder 3 is attached to the base 1, but in the second embodiment, five holders 3 are attached to a cap-like (hemispherical) base 11. When the base 11 is mounted on the head of the subject, the holder 3 is disposed so as to hit the frontal head, the back head, the left side head, the right side head, and the top of the head. Also. The base 11 is made of a stretchable material as in the first embodiment.
As described above, by attaching the plurality of holders 3 to the base 11, it is possible to simultaneously or sequentially measure all parts of the head with the base 11 being attached to the head. That is, even when measurement is performed on a plurality of locations on the head, it is easy to attach to the head. Also in such a case, since the base 11 is made of a stretchable material, all the holders 3 can be brought into close contact with the head with a uniform force.
FIG. 4 shows a probe device for a biological optical measurement device that measures the entire head of the frontal head, the back of the head, the left head, the right head, and the top of the head. It may be installed. For example, when it is desired to measure the forehead and the top of the head, only two holders for the forehead and the top of the head are installed.

FIG. 5 is a perspective view showing a biological light measuring device probe apparatus according to a third embodiment of the present invention. In the first and second embodiments, the hat-shaped bases 1 and 11 are used, but in the third embodiment, a band-shaped base 12 made of a material having a predetermined stretchability is used. A first surface fastener 13 is attached to one end of the base 12. A second surface fastener 14 detachably attached to the first surface fastener 13 is attached to the other end of the base 12. As the surface fasteners 13 and 14, for example, Velcro (registered trademark) is used. Other configurations are the same as those of the first embodiment.
Even when such a belt-like base 12 is used, the base 12 is made of a stretchable material, so that the holder 3 can be brought into close contact with the head with a uniform force, Installation is also easy.
As Example 4, although not particularly illustrated, an example in which the holder 3 is arbitrarily attached from the outside of the base 1 will be described. In Examples 1 to 3, it is described that the front part, the rear part, and the lateral surface of the head are measured. However, the difference from these Examples is that the holder 3 can be moved to a desired part.
Base holes 1a through which the probe mounting portion 3a passes are provided in the base 1 at two-dimensional equal intervals. Note that the width of the two-dimensional equal interval is equal to the width between the probes. The base 1 and the holder 3 are respectively provided with removable members such as Velcro (registered trademark) or fasteners. When attaching the holder 3 to the base 1, the probe mounting portion 3 a is passed through the base hole 1 a and fixed by a removable member.
When it is desired to obtain a signal at an obliquely forward or backward position of the head, the holder 3 is fixed to the base 1 with the mark 15 as a reference point before the head is mounted. After the head is mounted, the holder 3 is fixed to the base 1 so as to match the part where signals at the front and rear of the head are desired to be detected.
Thus, in this embodiment, the holder 3 can be attached to a desired position of the base 1. Therefore, by positioning the holder 3 freely, all the holders 3 are brought into close contact with the head with a uniform force, and any part of the head can be measured.
Note that the number and position of holders attached to the base are not limited to the above-described embodiments.
Further, the number of probe mounting portions provided in the holder is not particularly limited.
Furthermore, in the above example, the probe mounting portions are arranged in a lattice shape, but the arrangement of the probe mounting portions is not limited to the lattice shape.

Claims (14)

An optical fiber probe including at least one set of an irradiation unit that irradiates the subject with inspection light for measuring biological light, and a light receiving unit that receives the inspection light returning from the subject, and at least one for mounting the optical fiber probe A holder having two probe mounting portions, and a base made of a stretchable material so as to wrap at least one part of the head of the subject, the base corresponding to the distance between the optical fiber probes The base hole is open ,
The living body light measurement, wherein the base is formed in a hat shape, and the base formed in the hat shape is provided with an alignment mark for alignment with a reference position of a subject to be mounted. Probe device for equipment. The probe device for a living body light measurement device according to claim 1, wherein an elastic member such as rubber for fastening is provided on an edge portion of the base formed in the cap shape. 2. The attachment / detachment mechanism is provided on the holder, wherein the attachment / detachment mechanism is provided to attach / detach the optical fiber probe to / from the optical fiber probe attachment portion while the holder is attached to the base. A probe device for a biological light measurement device. Each of the optical fiber probe mounting portions extends in a direction perpendicular to the axial direction of the probe insertion hole having a circular cross section for receiving the optical fiber probe and the probe insertion hole, and is equally spaced along the inner peripheral surface of the probe insertion hole. Each of the optical fiber probes has an optical fiber for guiding inspection light, a cylindrical probe holder that is attached to the tip of the optical fiber, and is inserted into the probe insertion hole. A plurality of positioning grooves that are continuously spaced over the entire circumference of the outer periphery of the cylindrical probe holder and spaced apart from each other in the axial direction of the probe insertion hole. The portion receives a positioning ball and a compression spring that biases the positioning ball at the tip of the pin screwed into each of the pin screw holes. A screw pin having a vertical hole for holding, and the screw pin having the pin screw hole and the positioning ball and the compression spring cooperate with a positioning groove of the probe holder to constitute the optical fiber probe attaching / detaching mechanism. The probe device for a living body light measurement device according to claim 3 characterized by things. The peripheral portion of the base hole is sandwiched between the unscrewed portions of the plurality of screw pins and the outer surface of the holder, thereby preventing the optical fiber probe mounting portion from coming off from the base hole and the holder being The probe device for a living body light measuring device according to claim 4, wherein an inner surface of the base is attached. The said optical fiber probe mounting part is comprised integrally with the said holder, The probe apparatus for biological light measuring devices of Claim 1 characterized by the above-mentioned. The probe device for a biological optical measurement device according to claim 1, wherein the base is made of a breathable jersey cloth. The probe device for a living body light measurement apparatus according to claim 1, wherein the holder is made of a material having rigidity selected from plastic, ceramic, and metal. The probe device for a living body light measurement apparatus according to claim 1, wherein the holder is made of a material having low elasticity compared to the base. The probe device for a biological light measurement device according to claim 1, wherein the holder is attached to the inside of the base after the probe mounting portion is passed through the base hole. 2. The probe device for a living body light measurement apparatus according to claim 1, wherein the holder is attached to the base via an adhesive, a fastener that can be sewn or removed from the inside or the outside of the base. . The probe device for a biological light measurement apparatus according to claim 1, wherein a cushion material is provided on a side of the holder that directly contacts the subject head. 2. The probe device for a biological light measurement apparatus according to claim 1, wherein the shape of the holder is formed in accordance with the shape of the head corresponding to the measurement site of the subject. The probe apparatus for a biological light measurement apparatus according to claim 1, wherein the holder is attached to the base in accordance with a measurement site of a subject.