JPWO2019145880A5 - - Google Patents

Description

(wrap up)
In one embodiment of the invention, a system for imaging microscopic samples is provided. The system comprises a light source for exciting fluorescence from at least one sample, an excitation optical path comprising one or more objective lenses for directing light from the light source to an object plane coinciding with the at least one sample; a beam splitter disposed along the excitation optical path and configured to separate a portion of the light from the excitation optical path; and a portion of the light separated from the excitation optical path that detects at least one sample a photosensor configured to output an electrical signal representative of the light flux to a camera disposed in an image plane and configured to obtain an image of fluorescence emitted from at least one sample; a photosensor a controller, comprising an integrator configured to integrate an electrical signal from and produce an aggregated output; and a comparator configured to compare the integrated output to a predetermined threshold; and the controller controls at least the camera exposure time such that each sample receives substantially the same total flux for the duration of the camera exposure, which is terminated when a predetermined threshold is reached. do.

Other systems, methods, features and advantages of the invention will be or will become apparent to one with skill in the art upon inspection of the following figures and detailed description. It is intended that all such additional systems, methods, features and advantages be included within this description, be within the scope of the invention, and be protected by the accompanying claims. It is to be understood that both the foregoing general description of the invention and the following detailed description of the invention are illustrative and not limiting of the invention.
The present invention provides, for example, the following.
(Item 1)
A system for imaging a microscopic sample, comprising:
a light source for exciting fluorescence from at least one sample;
an optical excitation path comprising one or more objective lenses that direct light from the light source to an object plane coinciding with the at least one sample;
a beam splitter disposed along the optical excitation path and configured to separate a portion of the light from the optical excitation path;
an optical sensor configured to detect a portion of the light separated from the optical excitation path and output an electrical signal representative of the light flux to the at least one sample;
a camera configured to capture an image of fluorescence emitted from the at least one sample;
an integrator configured to integrate the electrical signal from the photosensor to produce an integrated output; and a comparator configured to compare the integrated output to a predetermined threshold. with a controller and
with
The controller at least lengthens the camera exposure such that each sample receives substantially the same total flux for the duration of the camera exposure, which is terminated when the predetermined threshold is reached. system to control.
(Item 2)
The controller, implemented by electronic circuitry or program code, or one of a combination of the two, integrates the electrical signal, produces the integrated output, and reduces the integrated output to the predetermined threshold value. The system of item 1, compared to.
(Item 3)
the controller is configured to initiate the camera exposure before or at the same time that the light source is switched on;
The integrator integrates the electrical signal from the light sensor after the light source is switched on.
3. The system of item 2, wherein the exposure time of the camera is terminated when the predetermined threshold is reached.
(Item 4)
4. The system of item 3, wherein the light source is switched off when the predetermined threshold is reached.
(Item 5)
The system of item 1, wherein the light source is switched off when the predetermined threshold is reached.
(Item 6)
The system of item 1, further comprising a filter set for fluorescence measurements.
(Item 7)
The system of item 1, wherein the light source comprises a light emitting diode.
(Item 8)
The system of item 1, wherein the light source is coupled into a microscope setup with an optical fiber.
(Item 9)
8. System according to item 7, wherein the optical fiber comprises a fiber guide or a fiber bundle.
(Item 10)
The system of item 1, wherein the one or more objectives allow multiple magnifications of the at least one sample.
(Item 11)
The system of item 1, further comprising a holder for a microplate holding multiple samples, wherein the camera measures multiple samples.
(Item 12)
12. The system of item 11, wherein the controller directs the measurement of the samples in sequence from one sample to another.
(Item 13)
12. The system of item 11, wherein the controller directs a time lapse sequence in which the same sample is measured multiple times.
(Item 14)
The system of item 1, wherein the controller directs a time lapse sequence of multiple measurements between different samples.
(Item 15)
The system of item 1, wherein the beam splitter is located inside a microscope setup where the camera is located.
(Item 16)
12. The system of item 11, wherein the beamsplitter is located outside the microscope setup where the camera is located.
(Item 17)
The system of item 1, wherein the fluorescence imaged by the camera does not pass through the beam splitter.
(Item 18)
A system for imaging a microscopic sample, comprising:
an optical excitation path that directs light from a light source to at least one sample;
an optical sensor configured to output an electrical signal representative of the light flux to the at least one sample;
a camera configured to receive an image of fluorescence emitted from the at least one sample;
controlling the camera exposure time such that each sample receives substantially the same total luminous flux for the duration of the camera exposure, which is terminated when a predetermined threshold representing the total luminous flux is reached. The controller and
A system comprising:
(Item 19)
A system for imaging a sample, comprising:
means for directing light from the light source to an object plane coinciding with the at least one sample;
means for measuring the intensity of said portion of light;
means for imaging fluorescence emitted from the at least one sample in response to exposure to incident light from the light source;
means for controlling the exposure time of each image obtained from said at least one sample such that, for a plurality of images obtained, each sample receives substantially the same total flux of said incident light;
A system comprising:
(Item 20)
A method for imaging a microscopic sample, comprising:
directing light from the light source to an object plane coinciding with the at least one sample;
separating a portion of the light to a photosensor and outputting an electrical signal representative of the flux to the at least one sample;
forming an image of fluorescence emitted from the at least one sample in response to exposure to incident light from the light source;
controlling the exposure time of each image obtained from the at least one sample such that, for the plurality of images obtained, each sample receives substantially the same total flux of the incident light;
A method, including
(Item 21)
integrating an electrical signal from the optical sensor to produce a summed output;
comparing the aggregated output to a predetermined threshold;
21. The method of item 20, further comprising:
(Item 22)
commencing the camera exposure before or at the same time that the light source is switched on;
integrating the electrical signal from the light sensor after the light source is switched on;
terminating the exposure time of the camera when the predetermined threshold is reached;
21. The method of item 20, further comprising:
(Item 23)
23. The method of item 22, further comprising turning off the light source when the predetermined threshold is reached.
(Item 24)
21. The method of item 20, further comprising turning off the light source when the predetermined threshold is reached.
(Item 25)
21. The method of item 20, further comprising measuring the samples in sequence from one sample to another.
(Item 26)
21. The method of item 20, further comprising measuring in a time lapse sequence in which the same sample is measured multiple times.
(Item 27)
21. The method of item 20, further comprising measuring in a time lapse sequence, measuring multiple times between different samples.
(Item 28)
A computer readable medium having program code which, when executed on a processor in the system of any one of items 1-19, comprises the steps of:
turning the light source on or off and directing the light to an object plane coinciding with the at least one sample;
measuring an electrical signal output from a photosensor that receives a portion of the light;
receiving from a camera an image of fluorescence emitted from the at least one sample in response to exposure to incident light from the light source;
controlling, with said camera, the exposure time of each image obtained from said at least one sample such that, for a plurality of images obtained, each sample receives substantially the same total flux of said incident light; and
A computer readable medium for implementing

A method for imaging a microscope sample integrates an electrical signal from optical sensor 230 (as in FIG. 2) to produce a summed or integrated output, and compares the summed or integrated output to a predetermined threshold. can do. The method may set the camera (eg, camera 280) into an exposure mode before or at the same time that the light source 210 is switched on. The method can start integrating the electrical signal from the light sensor after the light source 210 is switched on and turn off the camera when a predetermined threshold is reached. The method may turn off the light source 210 when a predetermined threshold is reached.

The program code further integrates, separately or in conjunction with the electronic circuitry, the electrical signal from the optical sensor to produce an aggregated output, and comparing the aggregated output to a predetermined threshold. may be executed. The program code (or electronic circuitry) may also initiate camera exposure before or at the same time that the light source is switched on. The program code (or electronic circuitry) may also begin integrating the electrical signal from the light sensor after the light source is switched on, and turn off the camera when a predetermined threshold is reached. The program code (or hardware) may also turn off the light source when a predetermined threshold is reached.

Claims (28)

A system for imaging a plurality of microscopic samples, comprising:
a light source for exciting fluorescence from the plurality of microscopic samples;
an optical excitation path comprising one or more objective lenses that direct light from the light source to an object plane coinciding with the plurality of microscope samples;
a beam splitter disposed along the optical excitation path and configured to separate a portion of the light from the optical excitation path;
an optical sensor configured to detect the portion of the light separated from the optical excitation path and output an electrical signal representative of the light flux to each of the plurality of microscopic samples ;
a camera configured to capture an image of fluorescence emitted from each of the plurality of microscopic samples ;
an integrator configured to integrate the electrical signal from the photosensor and produce an integrated output; and a comparator configured to compare the integrated output to a predetermined threshold. comprising a controller and
The controller controls the exposure of the camera such that each of the plurality of microscope samples simultaneously receives substantially the same total luminous flux for the duration of the exposure of the camera; the exposure is terminated when the predetermined threshold is reached;
The system , wherein the one or more objectives enable the camera to image each of the plurality of microscopic samples simultaneously. The controller integrates the electrical signal to produce the integrated output by one of electronic circuitry or program code , or a combination of the two, and compares the integrated output to the predetermined threshold. 3. The system of claim 1, implemented to compare. the controller is configured to initiate the exposure of the camera before or at the same time that the light source is switched on;
after the light source is switched on, the integrator integrates the electrical signal from the light sensor ;
3. The system of claim 2, wherein the exposure of the camera is terminated when the predetermined threshold is reached. 4. The system of claim 3, wherein the light source is switched off when the predetermined threshold is reached. 2. The system of claim 1, wherein the light source is switched off when the predetermined threshold is reached. 3. The system of claim 1, further comprising a filter set for fluorescence measurements. 3. The system of Claim 1, wherein the light source comprises a light emitting diode. 2. The system of claim 1, wherein said light source is coupled into said system with an optical fiber. 9. The system of Claim 8 , wherein the optical fiber comprises a fiber guide or fiber bundle. 2. The system of claim 1, wherein the one or more objective lenses allow multiple magnifications of the multiple microscope samples. 3. The system of claim 1, further comprising a holder for a microplate holding multiple samples, wherein the camera measures multiple samples. 12. The system of claim 11, wherein the controller directs the measurement of the samples in sequence from one sample to another. 12. The system of claim 11, wherein the controller directs a time lapse sequence in which the same sample is measured multiple times. 2. The system of claim 1, wherein the controller directs a time lapse sequence of multiple measurements between different samples. 2. The system of claim 1, wherein the beamsplitter is located inside the system where the camera is located. 12. The system of claim 11, wherein the beamsplitter is located outside the system where the camera is located. 2. The system of claim 1, wherein the fluorescence imaged by the camera does not pass through the beamsplitter. A system for imaging a plurality of microscopic samples, comprising:
an optical excitation path that directs light from a light source to the plurality of microscopic samples;
an optical sensor configured to output an electrical signal representative of the light flux to each of the plurality of microscopic samples ;
a camera configured to receive an image of fluorescence emitted from each of the plurality of microscopic samples ;
a controller configured to control the exposure of the camera such that each sample of a plurality of microscope samples simultaneously receives substantially the same total light flux for the duration of the exposure of the camera; and wherein the exposure of the camera is terminated when a predetermined threshold representing total luminous flux is reached . A system for imaging a plurality of microscopic samples, comprising:
means for directing light from a light source to an object plane coinciding with the plurality of microscope samples;
means for measuring the intensity of said portion of light;
means for imaging fluorescence emitted from each of said plurality of microscopic samples in response to exposure to incident light from said light source;
For the plurality of images obtained, each image obtained from each of the plurality of microscopic samples such that each sample of the plurality of microscopic samples simultaneously receives substantially the same total flux of the incident light. and means for controlling exposure . A method for imaging a plurality of microscopic samples, comprising:
directing light from a light source to an object plane coinciding with the plurality of microscope samples;
separating a portion of the light onto an optical sensor and outputting an electrical signal representing the light flux to each of the plurality of microscopic samples ;
forming an image of fluorescence emitted from each of the plurality of microscopic samples in response to exposure to incident light from the light source;
exposing each image obtained from each of said plurality of microscopic samples such that, for the obtained plurality of images, each sample of said plurality of microscopic samples simultaneously receives substantially the same total flux of said incident light; and . integrating an electrical signal from the optical sensor to produce a summed output;
21. The method of claim 20, further comprising: comparing said aggregated output to a predetermined threshold. commencing the exposure of the camera before or at the same time that the light source is switched on;
integrating the electrical signal from the light sensor after the light source is switched on;
22. The method of claim 21 , further comprising: terminating the exposure of the camera when the predetermined threshold is reached. 23. The method of Claim 22, further comprising turning off the light source when the predetermined threshold is reached. 22. The method of Claim 21 , further comprising turning off the light source when the predetermined threshold is reached. 21. The method of claim 20, further comprising measuring the samples in sequence from one sample to another. 21. The method of claim 20, further comprising measuring in a time lapse sequence in which the same sample is measured multiple times. 21. The method of claim 20, further comprising measuring in a time lapse sequence, measuring multiple times between different samples. A computer readable medium having a program code which, when executed on a processor in a system according to any one of claims 1-19, comprises the following steps:
turning the light source on or off and directing the light to an object plane coinciding with the plurality of microscope samples;
measuring an electrical signal output from a photosensor that receives a portion of the light;
receiving from a camera an image of fluorescence emitted from each of the plurality of microscopic samples in response to exposure to incident light from the light source;
The plurality of images acquired from each of said plurality of microscopic samples by said camera such that each sample of said plurality of microscopic samples simultaneously receives substantially the same total flux of said incident light. A computer readable medium for performing the steps of: controlling the exposure of each image;