Patent application number | Description | Published |
20100296093 | APPARATUS AND METHODS USING HOLLOW-CORE FIBER TAPERS - An optical device and methods of using an optical device are provided. The optical device includes a hollow-core fiber including a first portion and a second portion. The first portion includes a hollow core having a first diameter. The second portion includes a hollow core having a second diameter smaller than the first diameter. The difference between the first diameter and the second diameter is less than 10% of the first diameter. | 11-25-2010 |
20110273712 | APPARATUS AND METHODS USING HOLLOW-CORE FIBER TAPERS - An optical device and methods of using an optical device are provided. The optical device includes a hollow-core fiber including a first portion and a second portion. The first portion includes a hollow core having a first diameter. The second portion includes a hollow core having a second diameter smaller than the first diameter. The difference between the first diameter and the second diameter is less than 10% of the first diameter. | 11-10-2011 |
20120063664 | INERTIAL PARTICLE FOCUSING FLOW CYTOMETER - A flow cytometry system includes an inertial particle focusing device including a plurality of substantially parallel microchannels formed in a substrate, each microchannel having a width to height ratio in the range of 2:3 to 1:4, an analyzer disposed adjacent the inertial particle focusing device such that the analyzer is configured to detect a characteristic of particles in the inertial particle focusing device, and a controller connected to the analyzer and configured to direct the detection of the characteristic of the particles. | 03-15-2012 |
20120148141 | COMPACT AUTOMATED SEMEN ANALYSIS PLATFORM USING LENS-FREE ON-CHIP MICROSCOPY - A compact and light-weight lens-free platform to conduct automated semen analysis is disclosed. The device employs holographic on-chip imaging and does not require any lenses, lasers or other bulky optical components to achieve phase and amplitude imaging of sperm a relatively large field-of-view with an effective numerical aperture of approximately 0.2. A series of digital image frames is obtained of the sample. Digital subtraction of the consecutive lens-free frames, followed by processing of the reconstructed phase images, enables automated quantification of the count, the speed and the dynamic trajectories of motile sperm, while summation of the same frames permits counting of immotile sperm. | 06-14-2012 |
20120157160 | COMPACT WIDE-FIELD FLUORESCENT IMAGING ON A MOBILE DEVICE - Wide-field fluorescent imaging on a mobile device having a camera is accomplished with a compact, light-weight and inexpensive optical components that are mechanically secured to the mobile device in a removable housing. Battery powered light-emitting diodes (LEDs) contained in the housing pump the sample of interest from the side using butt-coupling, where the pump light is guided within the sample holder to uniformly excite the specimen. The fluorescent emission from the sample is then imaged using an additional lens that is positioned adjacent to the existing lens of the mobile device. A color filter is sufficient to create the dark-field background required for fluorescent imaging, without the need for expensive thin-film interference filters. | 06-21-2012 |
20120218379 | INCOHERENT LENSFREE CELL HOLOGRAPHY AND MICROSCOPY ON A CHIP - A system for imaging a cytological sample includes a sample holder configured to hold a cytological sample. A spatial filter is disposed at a distance z | 08-30-2012 |
20120248292 | LENS-FREE WIDE-FIELD SUPER-RESOLUTION IMAGING DEVICE - A system for imaging objects within a sample includes an image sensor and a sample holder configured to hold the sample, the sample holder disposed adjacent to the image sensor. The system further includes an illumination source configured to scan in two or three dimensions relative to the sensor array and illuminate the sample at a plurality of different locations. The illumination source may include, by way of example, LEDs, laser diodes, or even a screen or display from a portable electronic device. The system includes least one processor configured to reconstruct an image of the sample based on the images obtained from illumination source at the plurality of different scan positions. | 10-04-2012 |
20130157351 | COMPACT WIDE-FIELD FLUORESCENT IMAGING ON A MOBILE DEVICE - Wide-field fluorescent imaging on a mobile device having a camera is accomplished with a compact, light-weight and inexpensive optical components that are mechanically secured to the mobile device in a removable housing. Battery powered light-emitting diodes (LEDs) contained in the housing pump the sample of interest from the side using butt-coupling, where the pump light is guided within the sample holder to uniformly excite the specimen. The fluorescent emission from the sample is then imaged using an additional lens that is positioned adjacent to the existing lens of the mobile device. A color filter is sufficient to create the dark-field background required for fluorescent imaging, without the need for expensive thin-film interference filters. | 06-20-2013 |
20130193544 | MICROSCOPY METHOD AND SYSTEM INCORPORATING NANOFEATURES - A lensfree imaging and sensing device includes an image sensor comprising an array of pixels and a substantially optically transparent layer disposed above the image sensor. Nano-sized features that support surface plasmon waves are populated on the substantially optically transparent layer separating the image sensor from the nano-sized features. The nano-sized features may include apertures through a substantially optically opaque layer (e.g., metal layer) or they may include antennas. An illumination source is provided that is configured to illuminate a sample. At least one processor is operatively coupled to the image sensor. Changes to the detected transmission pattern at the image sensor are used to sense conditions at or near the surface containing the nano-sized features. Conditions may include binding events or other changes to the index of refraction occurring near the surface of the device. | 08-01-2013 |
20130203043 | PORTABLE RAPID DIAGNOSTIC TEST READER - A portable rapid diagnostic test reader system includes a mobile phone having a camera and one or more processors contained within the mobile phone and a modular housing configured to mount to the mobile phone. The modular housing including a receptacle configured to receive a sample tray holding a rapid diagnostic test. At least one illumination source is disposed in the modular housing and located on one side of the rapid diagnostic test. An optical demagnifier is disposed in the modular housing interposed between the rapid diagnostic test and the mobile phone camera. | 08-08-2013 |
20130258091 | METHOD AND DEVICE FOR HOLOGRAPHIC OPTO-FLUIDIC MICROSCOPY - A method and system of imaging a moving object within a microfluidic environment includes illuminating a first side of a flow cell configured to carry the moving object within a flow of carrier fluid with an illumination source emitting at least partially coherent light, the at least partially coherent light passing through an aperture prior to illuminating the flow cell. A plurality of lower resolution frame images of the moving object are acquired with an image sensor disposed on an opposing side of the flow cell, wherein the image sensor is angled relative to a direction of flow of the moving object within the carrier fluid. A higher resolution image is reconstructed of the moving object based at least in part on the plurality of lower resolution frame images. | 10-03-2013 |
20130280752 | LENS-FREE TOMOGRAPHIC IMAGING DEVICES AND METHODS - A system for three dimensional imaging of an object contained within a sample includes an image sensor, a sample holder configured to hold the sample, the sample holder disposed adjacent to the image sensor, and an illumination source comprising partially coherent light. The illumination source is configured to illuminate the sample through at least one of an aperture, fiber-optic cable, or optical waveguide interposed between the illumination source and the sample holder, wherein the illumination source is configured to illuminate the sample through a plurality of different angles. | 10-24-2013 |
20140120563 | ALLERGEN TESTING PLATFORM FOR USE WITH MOBILE ELECTRONIC DEVICES - An allergy testing system for use with a mobile electronic device having a camera includes a housing that can be attached to the mobile electronic device. First and second light sources within the housing are configured to illuminate, respectively, a test sample and a control sample. A colorimetric assay is performed on the test sample and the control sample. The first light source and the second light source are activated and the camera of the mobile electronic device captures images of transmitted light. The relative intensity of transmitted light is then used by software loaded on the mobile electronic device to determine a relative absorbance value. The relative absorbance value is used, together with a calibration curve, to measure the concentration of a particular allergen within the test sample. Based on the concentration of the allergen the test sample can be labeled as either “positive” or “negative.” | 05-01-2014 |
20140160236 | LENSFREE HOLOGRAPHIC MICROSCOPY USING WETTING FILMS - A method of imaging a sample includes forming a monolayer wetting layer over a sample containing objects therein. A plurality of lower resolution images are obtained of the sample interposed between an illumination source and an image sensor, wherein each lower resolution image is obtained at discrete spatial locations. The plurality of lower resolution images of the sample are converted into a higher resolution image. One or more of an amplitude image and a phase image are reconstructed of the objects contained within the sample. | 06-12-2014 |
20140300696 | MASKLESS IMAGING OF DENSE SAMPLES USING MULTI-HEIGHT LENSFREE MICROSCOPE - A method of imaging includes illuminating a sample spaced apart from an image sensor at a multiple distances. Image frames of the sample obtained at each distance are registered to one another and lost phase information from the registered higher resolution image frames is iteratively recovered. Amplitude and/or phase images of the sample are reconstructed based at least in part on the recovered lost phase information. | 10-09-2014 |