The present invention relates to a substrate collecting device.
There has been known a device adapted to divide a glass substrate, to which a biological tissue section has been attached, together with the section in a state wherein the glass substrate has been attached to a sheet, and to collect some of the divided substrates together with section fragments, a desired substrate can be selectively collected by pushing, through the sheet, the back surface of the substrate facing downward thereby to cause the substrate to come off from the sheet and fall.
One aspect of the present invention provides a substrate collecting device that detaches and collects substrates among a plurality of substrates, which have been attached to a sheet such that the substrates can be detached by carrying out a predetermined operation, from the sheet, the substrate collecting device including: a first stage configured to move in a horizontal direction, the stage capable of holding a sheet, the sheet comprising a first surface and a plurality of substrates on a second surface, an optical system that observes one or more of the plurality of substrates on the stage, a collector that collects one or more of the plurality of substrates that is removed from the sheet, and a second stage that is capable of moving the optical system and the collector in the horizontal direction, wherein the second stage is configured to have a first position and a second position, the first position is such that the optical system is substantially vertically away from the second surface of the sheet and the second position is such that the collector is substantially vertically away from the second surface of the sheet. Furthermore, the substrate collecting device may conclude a sampler that is configured to cause at least one of the plurality of the substrates to be removed from the sheet.
According to one aspect of the present invention, the sheet to which the substrates have been attached is placed on the first stage, the position of the first stage is adjusted while observing a desired substrate by the optical system such that the substrate is disposed at a predetermined relative position with respect to the sampler, and the substrate disposed at the predetermined relative position is detached and dropped by the sampler, thereby allowing the desired substrate to be collected by the collector. Here, the positions of the optical system and the collector can be switched between the first position and the second position by the second stage, thereby allowing the optical system and the collector to be alternatively disposed substantially vertically below the first stage, while still adopting an inverted type optical design whereby to observe the substrate on the first stage through the optical system from below the first stage.
In this case, the movement range of the first stage is a sufficiently narrow range required for positioning a substrate relative to the sampler, so that the mechanism for moving the first stage has only to have a jogging function, thus permitting a simplified moving mechanism. Meanwhile, the accuracy for positioning the optical system and the collector relative to the sampler is not strictly required, as compared with that for the first stage, so that adequate positioning accuracy therefor can be achieved by the positioning carried out by the second stage.
In the aforesaid invention, the optical system may be provided with a reflector that reflects, at the first position, an image of at least one of the plurality of substrates the substrate on the first stage in a direction that intersects with a vertical direction, and a imaging sensor that acquires the image reflected by the reflector.
This arrangement enables the imaging sensor to acquire the image of the substrate, which is transmitted from the reflector, at an arbitrary position, so that the degrees of freedom of the disposition of the imaging sensor and the optical design can be increased. Further, the second stage is provided with the reflector, which is smaller and lighter than the imaging sensor, thus allowing the configuration of the second stage to be further simplified.
In the aforesaid invention, the substrates may be attached to the second surface of the sheet such that the substrates can be detached by being pushed from the first surface of the sheet, and the sampler may be provided with a pushing end that is configured to push the first surface of the sheet opposite at least one of the plurality of the substrates and a moving mechanism that moves the pushing end in the substantially vertical direction.
With this arrangement, some substrates disposed substantially vertically below the pushing end can be selectively detached from the sheet and dropped by a simple operation of merely moving the pushing member toward the substrates by the moving mechanism and pushing the substrates by the pushing end through the sheet.
In the aforesaid invention, the substrates may be attached to the sheet by an adhesive agent, the adhesive force of which is decreased by the irradiation of ultraviolet rays, and the sampler may have an emitting surface that irradiates ultraviolet rays to the predetermined relative position.
Thus, some substrates disposed at the predetermined relative position can be selectively detached from the sheet and dropped by a simple operation of merely emitting ultraviolet rays from the emitting surface.
The following will describe a substrate collecting device 1 according to an embodiment of the present invention with reference to the accompanying drawings.
As illustrated in
As illustrated in
The back surface of each of the substrates 2 is detachably attached to the sheet 11 by an adhesive agent having an appropriate adhesive force. More specifically, the substrate 2 is attached to the sheet 11 with an adhesive force that allows the substrate 2 to come off from the sheet 11 when the back surface of the substrate 2 is pushed from the sheet 11 side with a force that is larger than the weight of the substrate 2 itself and that is equal to or larger than a predetermined magnitude. Further, the substrates 2 and the sheet 11 are optically transparent or translucent.
The sheet 11 is substantially horizontally placed on the first stage 3, which can be moved in the substantially horizontal direction. Further, the first stage 3 has a window 14 that penetrates in the direction of the thickness at the center thereof.
The sampler 4 has a thin and long, straight rod-shaped needle member (pushing member) 12 and a manipulator 13. The distal surface (pushing end) of the needle member 12 has a diameter dimension that is substantially equal to or less than the substrate 2. The manipulator 13 is capable of holding the needle member 12 with the distal end thereof facing substantially vertically downward and moving the needle member 12 in the substantially vertical direction. The manipulator 13 is adapted to move the needle member 12, which is held by the manipulator 13, in the vertical direction along the longitudinal direction thereof by being operated in the substantially vertical direction under the control by the controller 10.
The objective lens 5, the illuminating section 6 and the collector 7 are provided on the same moving unit 8. To be specific, the objective lens 5 is fixed to the moving unit 8 with the optical axis thereof set in the substantially vertical direction. Through the objective lens 5, the substrate 2 placed at the position of the window 14 of the first stage 3 is observed from below. The image formed by the objective lens 5 is displayed on the display section 9 through an optical system, which is not illustrated.
The illuminating section 6 is an annular lamp mounted on the distal surface of the objective lens 5 such that the lamp surrounds the distal surface and is composed of, for example, a white LED or an optical fiber. The illuminating section 6 irradiates illumination light L to the substrate 2 on the first stage 3 from below. The illuminating section 6 may be constructed to irradiate light that has an excitation wavelength of a fluorescent material contained in the section X to the substrate 2 as the illumination light L so that the fluorescence from the section X is observed through the objective lens 5.
The collector 7 is shaped as a hole which is formed in the moving unit 8 and which supports the bottom of a collecting container 15 shaped like a centrifugal tube.
The moving unit 8 is provided such that it can be moved in the horizontal direction by a direct acting guide, which is not illustrated. Further, the moving unit 8 is adapted to be positioned at two positions by a positioning mechanism, such as a click mechanism provided on the direct acting guide. More specifically, the moving unit 8 is provided such that it is alternatively positioned at a first position at which the optical axis of the objective lens 5 is disposed vertically below the needle member 12 and a second position at which the collector 7 is disposed vertically below the needle member 12. In
The controller 10 is adapted to control the operations of the first stage 3, the illuminating section 6, the moving unit 8 and the manipulator 13 in response to input operations by an operator. The operations the input to the controller 10 by the operator are carried out by using, for example, a user interface, which is provided on the controller 10 and which is not illustrated.
The operations of the first stage 3, the illuminating section 6, the moving unit 8, and the manipulator 13 may be controlled by the manual operations by the operator.
The operation of the substrate collecting device 1 constructed as described above will now be explained.
In order to collect some of the plurality of the substrates 2, which have been attached to the sheet 11, by the substrate collecting device 1 according to the present embodiment, the sheet 11 is first placed on the first stage 3. At this time, the sheet 11 is set on the first stage 3 such that the substrates 2 are disposed at the window 14 and also the substrates 2 are disposed on the bottom side of the sheet 11. A part of the sheet 11 may be fixed to the first stage 3 by a clip or the like such that the position of the sheet 11 is stabilized on the first stage 3.
Then, the operator disposes the moving unit 8 at the first position and turns on the illuminating section 6. Thus, the substrates 2 on the first stage 3 are observed through the objective lens 5 and the images of the substrates 2 are displayed on the display section 9. At this time, the substrates 2 and the sheet 11 are transparent or translucent and the section X attached to the substrate 2 is sufficiently thin, so that the needle member 12 disposed behind the sheet 11 relative to the objective lens 5 can be also observed through the objective lens 5.
The operator adjusts the positions of the substrates 2 relative to the needle member 12 by moving the first stage 3 in the horizontal direction and the first stage 3 is positioned such that the one desired substrate 2 overlaps the distal surface of the needle member 12 in the image displayed on the display section 9. Subsequently, the operator moves the moving unit 8 to the second position to dispose the collecting container 15 located at the collector 7 at substantially vertically below the needle member 12, as illustrated in
The substrate 2 pushed by the distal surface of the needle member 12 comes off from the sheet 11 and falls substantially vertically downward to be collected into the collecting container 15. To collect two or more substrates 2, the moving unit 8 is moved back to the first position, and the procedure from the step for positioning the first stage 3 to the step for pushing the substrate 2 by the needle member 12 is repeated.
As described above, the present embodiment makes it possible to both observe and collect the substrates 2 by alternatively placing the objective lens 5 and the collecting container 15 substantially vertically below the first stage 3 by switching the position of the moving unit 8 while still adopting by the inverted type optical design whereby to observe the substrates 2 on the first stage 3 from below the first stage 3 through the objective lens 5.
In this case, the movement range required of the first stage 3 is a sufficiently narrow range required for the positioning between the distal surface of the needle member 12 and the substrate 2. Hence, the moving mechanism of the first stage 3 may be provided with a jogging mechanism that moves with a minute travel distance within a relatively narrow movement range, thus making it possible to simplify the construction of the moving mechanism of the first stage 3.
The accuracy for positioning the first stage 3 relative to the needle member 12 and the substrate 2 is higher than the accuracy for positioning the objective lens 5 and the collector 7 relative to the needle member 12 and the substrate 2. Hence, for the objective lens 5 and the collector 7, positioning accuracy that is high enough for practical use can be achieved by a positioning mechanism, such as a click mechanism, even when the objective lens 5 and the collector 7 are moved for a relatively long distance by the moving unit 8.
In the present embodiment, the illuminating section 6 is adapted to be integrally moved by the moving unit 8 together with the objective lens 5 and the collector 7. Alternatively, however, the illuminating section 6 may be provided independently of the moving unit 8. For example, the illuminating section 6 may be fixed to the first stage 3.
With this arrangement, the substrates 2 on the first stage 3 can be illuminated by the illuminating section 6 at an arbitrary timing independently of the positional relationship between the objective lens 5 and the first stage 3.
Further, in the present embodiment, the objective lens 5 has been used as the means for observing the substrates 2. Alternatively, however, a camera (imaging sensor) 16 may be used. In this case, a mirror (reflector) 17 may be provided, which is fixed to a moving unit 8 and laterally reflects the image of a substrate 2 positioned at a window 14 at a first position and the camera 16 is disposed in the direction of reflection from the mirror 17, as illustrated in
Transmitting the image of the substrate 2 on the first stage 3 to the camera 16 by the mirror 17 as described above makes it possible to provide the camera 16 independently of the moving unit 8, thus permitting a higher degree of freedom of the design of the camera 16. Further, the mirror 17 provided on the moving unit 8 is smaller and lighter than the objective lens 5 or the camera 16, so that the construction of the moving unit 8 can be simplified.
Further, in the present embodiment, the description has been given of the hole for accommodating the single collecting container 15 as the collector 7; however, the configuration of the collector 7 is not limited thereto. The collector may be a groove in which a microplate having a plurality of holes is installed. Further, the collector may be formed of a member having adhesiveness to capture the falling substrates 2 by the adhesiveness.
Further, a moving unit 8 may be provided with a plurality of collectors 7 and the moving unit 8 may be constructed such that the moving unit 8 can be positioned at three or more positions at which the individual collectors 7 are disposed substantially vertically below needle members 12. Further, the moving unit 8 may be rotatively moved.
This arrangement also makes it possible to alternatively position the objective lens 5 and the collecting containers 15 substantially vertically below the needle member 12 by the moving unit 8′.
Further, in the present embodiment, the sampler 4 is provided with the needle member 12; however, the construction of the sampler 4 is not limited thereto. For example, the sampler 4 may be provided with a tubular member in place of the needle member 12. Further, the needle member 12 may be inserted in the tubular member such that the distal end of the needle member 12 juts out.
Further, a plurality of needle members 12 may be bundled and held by the manipulator 13, or a crown needle having the distal portion thereof split into a plurality of ends may be used as the needle member 12. In the case where the sampler 4 has the needle member 12 with a plurality of distal surfaces as described above, the sampler 4 may be constructed such that a plurality of the substrates 2 are simultaneously pushed by the plurality of the distal surfaces of the needle member 12 to detach and drop the substrates 2.
Further, in place of the needle member 12, an optical fiber 19 having a small-diameter distal surface (emitting surface) 19a, as illustrated in
Number | Date | Country | Kind |
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2012-234749 | Oct 2012 | JP | national |
The present application is a U.S. continuation application based on the PCT International Patent Application, PCT/JP2013/077162, filed on Oct. 4, 2013; the contents of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/JP2013/077162 | Oct 2013 | US |
Child | 14695108 | US |