US2018364159A1PendingUtilityA1

Particle Detection Using Reflective Surface

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Assignee: CAPTL LLCPriority: Apr 3, 2015Filed: Aug 23, 2018Published: Dec 20, 2018
Est. expiryApr 3, 2035(~8.7 yrs left)· nominal 20-yr term from priority
B01L 2300/168G01N 21/47G01N 2015/1006B01L 3/502715G01N 21/55G01N 2021/6463G01N 21/645G01N 21/4788G01N 15/1484G01N 15/147G01N 15/1434G01N 15/1425B01L 2300/0806B01L 2400/049G01N 2021/6439G01N 15/1429B01L 2400/0406B01L 2300/0654B01L 2400/0409
60
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Claims

Abstract

An example assembly includes a target holder that retains a target in a detection region. Areflective surface reflects at least part of a focused spot of light to provide resultant light. An irradiation system irradiates at least part of the detection region with the focused spot of light. A motion system causes motion of the focused spot of light relative to the reflective surface. A detection system detects the resultant light. An example device, e.g., a lab-on-chip, includes a substrate, a sample inlet, and a reflective grating. The grating is retains a fluidic sample in a detection region fluidically connected to the sample inlet. The detection region is operatively arranged with respect to the reflective grating so that at least a portion of light passing through the detection region towards the reflective grating also passes through the detection region after reflecting off the reflective grating.

Claims

exact text as granted — not AI-modified
1 . An assembly, comprising:
 a target holder configured to retain a target in a detection region, wherein the target holder comprises a reflective surface configured to reflect at least part of a focused spot of light to provide resultant light;   an irradiation system configured to irradiate at least part of the detection region with the focused spot of light;   a motion system configured to cause motion of the focused spot of light relative to the reflective surface; and   a detection system configured to detect the resultant light.   
     
     
         2 . The assembly according to  claim 1 , further comprising a sample-delivery system configured to apply a fluidic sample comprising the target to the at least part of the detection region. 
     
     
         3 . The assembly according to  claim 2 , wherein:
 the reflective surface comprises a reflective grating;   the irradiation system is further configured to provide the focused spot of light, which comprises light of a predetermined wavelength;   the irradiation system comprises a lens having a predetermined numerical aperture and being arranged to focus the light of the predetermined wavelength to provide the focused spot of light;   the reflective grating has a pitch exceeding a reference pitch substantially equal to a result of dividing the predetermined wavelength by twice the numerical aperture;   the fluidic sample comprises a fluid having a predetermined refractive index; and   the reflective grating includes at least one groove having a depth substantially between a first reference value and a second reference value, the first reference value being the result of dividing the predetermined wavelength by the product of sixteen and the refractive index and the second reference value being substantially three times the first reference value.   
     
     
         4 . The assembly according to any one of  claims 1 - 3 , wherein:
 the detection system comprises at least one split photodetector configured to provide a plurality of detection signals; and   the assembly further comprises a data-processing system configured to determine, based at least in part on at least two of the plurality of detection signals, at least one of a sum signal, a transverse push-pull signal, or a radial push-pull signal.   
     
     
         5 . The assembly according to  claim 4 , wherein:
 the irradiation system is further configured to provide the focused spot of light, which comprises light of a predetermined wavelength; and   the detection system further comprises at least one optical detector configured to detect light of a different wavelength than the predetermined wavelength and to provide a detection signal corresponding to the light of the different wavelength.   
     
     
         6 . The assembly according to  claim 5 , further comprising a gating system configured to provide a particle signal associated with a temporal overlap between at least one of the plurality of detection signals and the detection signal corresponding to the light of the different wavelength. 
     
     
         7 . The assembly according to any one of  claims 1 - 6 , wherein:
 the reflective surface comprises a reflective grating having at least one groove; and   the motion system is further configured to cause relative motion of the focused spot of light substantially across the at least one groove.   
     
     
         8 . A device, comprising:
 a substrate;   a sample inlet associated with the substrate; and   a reflective grating associated with the substrate,   wherein:
 the reflective grating is configured to retain a fluidic sample in a detection region; 
 the detection region is fluidically connected to the sample inlet; and 
 the detection region is operatively arranged with respect to the reflective grating so that at least a portion of light passing through the detection region towards the reflective grating also passes through the detection region after reflecting off the reflective grating. 
   
     
     
         9 . The device according to  claim 8 , further including a cover spaced apart from the reflective grating and arranged so that the detection region is at least partly between the reflective grating and the cover, wherein the cover is at least partly transparent to the at least a portion of the light. 
     
     
         10 . The device according to either  claim 8  or  9 , further comprising a reservoir fluidically connected to the detection region and spaced apart from the sample inlet. 
     
     
         11 . The device according to any one of  claims 8 - 10 , wherein the reflective grating comprises at least one groove, and the at least one groove comprises at least two of: a spiral groove portion, a straight groove portion, or a circular groove portion. 
     
     
         12 . The device according to any one of  claims 8 - 11 , wherein:
 the sample inlet is configured to receive a provided sample; and   the device further comprises a filter element operatively arranged to filter the provided sample to provide the fluidic sample.   
     
     
         13 . The device according to any one of  claims 8 - 11 , wherein the substrate is a disc-format substrate. 
     
     
         14 . The device according to any one of  claims 8 - 11 , wherein:
 the sample inlet is one of a plurality of spaced-apart sample inlets of the device;   the detection region is one of a plurality of detection regions of the device; and   individual detection regions of the plurality of detection regions are fluidically connected to at least one of the plurality of sample inlets.   
     
     
         15 . A method, comprising:
 disposing a fluidic sample comprising a target over a reflective surface;   irradiating the reflective surface using a spot of light; and   detecting resultant light from the reflective surface.   
     
     
         16 . The method according to  claim 15 , further comprising causing the fluidic sample to flow through a flow channel across the reflective surface and causing the spot of light to move with respect to the reflective surface at least partly across the flow channel. 
     
     
         17 . The method according to either  claim 15  or  16 , wherein the reflective surface is associated with a disc; and
 wherein the method further comprises:
 rotating the disc, wherein the disc moves with respect to the spot of light during the rotating and the reflective surface comprises at least one track; 
 irradiating the reflective surface during the rotating; and 
 causing the spot of light to move to follow the track of the reflective surface. 
 
 
     
     
         18 . The method according to any one of  claims 15 - 17 , further comprising:
 applying a dye to the fluidic sample before the disposing; and   detecting light emitted by the dye in response to the irradiating using the spot of light.   
     
     
         19 . The method according to any one of  claims 15 - 18 , wherein the target comprises at least two portions having respective, different refractive indices. 
     
     
         20 . The method according to  claim 19 , wherein the fluidic sample has a refractive index different from each of the refractive indices of the target.

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