Patent application number | Description | Published |
20090139332 | Method for non-contact particle manipulation and control of particle spacing along an axis - Method and system for uniformly spacing particles in a flowing system comprising suspending particles in an elongated fluid filled cavity; exposing said cavity to an axial acoustic standing wave field, wherein said axial acoustic standing wave field drives said particles to nodal and anti-nodal positions along the center axis of said cavity to result in uniformly spaced particles; and focusing said particles to the center axis of said cavity. | 06-04-2009 |
20110134426 | APPARATUSES, SYSTEMS, METHODS, AND COMPUTER READABLE MEDIA FOR ACOUSTIC FLOW CYTOMETRY. - A flow cytometer includes a capillary having a sample channel; at least one vibration producing transducer coupled to the capillary, the at least one vibration producing transducer being configured to produce an acoustic signal inducing acoustic radiation pressure within the sample channel to acoustically concentrate particles flowing within a fluid sample stream in the sample channel; and an interrogation source having a violet laser and a blue laser, the violet and blue lasers being configured to interact with at least some of the acoustically concentrated particles to produce an output signal. | 06-09-2011 |
20120064639 | STABLE ELASTOMERIC NEGATIVE ACOUSTIC CONTRAST PARTICLES AND THEIR USE IN ACOUSTIC RADIATION FIELDS - We describe methods for synthesis and formulations of stable elastomeric negative acoustic contrast particles with controllable compressibility and density. These elastomeric negative acoustic contrast particles have a density/compressibility ratio that is less than that of water and therefore exhibit negative acoustic contrast under acoustic radiation exposure. This negative acoustic contrast allows our elastomeric negative acoustic contrast particles to be acoustically manipulated (e.g. separated) differently from other components (e.g. cells) within an aqueous solution. This disclosure also describes methods for biofunctionalization of the elastomeric negative acoustic contrast particles and as an example their use as platforms for bioassays. Potential applications of these elastomeric negative acoustic contrast particles include sensitive bioassays based on acoustic flow cytometry and other types of techniques that utilize acoustic fields, including ultrasound imaging and ultrasound triggered drug delivery. | 03-15-2012 |
20120140205 | METHODS AND SYSTEMS FOR CONTROLLING THE FLOW OF PARTICLES FOR DETECTION - A method of focusing particles is provided. The method includes transiting a fluid containing particles therein through a channel at a flow rate and adjusting the flow rate for a desired transit time through an interrogation zone through which a light from an excitation source passes. The method further includes optically exciting the particles with the excitation source, detecting an optical signal from the particles, and analyzing the optical signal. The particles may be droplets. Further, the particles may transit the interrogation zone in single file. A system of focusing particles is also provided. The system includes a channel having an inlet for accepting a fluid containing particles. The system further includes a flow adjuster configured to adjust the flow rate for a desired transit time through an interrogation zone, a light source configured to optically excite the particles, and a detector configured to detect optical signals from the particles. | 06-07-2012 |
20120227471 | SAMPLING PROBES, SYSTEMS, APPARATUSES, AND METHODS - A sampling system is provided. The sampling system includes a housing. Mounted to the housing is a Hall effect sensor. A probe configured to contact a sample is inserted into the housing. The probe includes an elongated portion and a restorative spring inserted onto the elongated portion of the probe. The restorative spring provides sufficient restorative force to return the probe to a relaxed position. The Hall effect sensor is configured to sense a field strength generated by the proximity of the restorative spring of the probe in the extended position. | 09-13-2012 |
20120298236 | Method for Non-Contact Particle Manipulation and Control of Particle Spacing Along an Axis - Method and system for uniformly spacing particles in a flowing system comprising suspending particles in an elongated fluid filled cavity; exposing said cavity to an axial acoustic standing wave field, wherein said axial acoustic standing wave field drives said particles to nodal and anti-nodal positions along the center axis of said cavity to result in uniformly spaced particles; and focusing said particles to the center axis of said cavity. | 11-29-2012 |
20130000421 | MEDIUM SWITCHING SYSTEMS AND METHODS USING ACOUSTIC RADIATION PRESSURE - The present invention comprises methods and systems that use acoustic radiation pressure. | 01-03-2013 |
20130292582 | Methods and Systems for Controlling the Flow of Particles for Detection - A method of focusing particles is provided. The method includes transiting a fluid containing particles therein through a channel at a flow rate and adjusting the flow rate for a desired transit time through an interrogation zone through which a light from an excitation source passes. The method further includes optically exciting the particles with the excitation source, detecting an optical signal from the particles, and analyzing the optical signal. The particles may be droplets. Further, the particles may transit the interrogation zone in single file. A system of focusing particles is also provided. The system includes a channel having an inlet for accepting a fluid containing particles. The system further includes a flow adjuster configured to adjust the flow rate for a desired transit time through an interrogation zone, a light source configured to optically excite the particles, and a detector configured to detect optical signals from the particles. | 11-07-2013 |
20140147860 | Acoustic Cytometry Methods and Protocols - Various embodiments disclosed herein comprise acoustic cytometry based methods, kits, computer software methods and systems to analyze a variety of bioparticles. In one embodiment, a method for analyzing bioparticles comprises: acoustically focusing one or more bioparticles through an interrogation zone; optically exciting the one or more bioparticles in the interrogation zone with an excitation source; detecting an optical signal from the bioparticles; and analyzing the optical signal to characterize at least one quality or quantity parameter of the bioparticles. Properties of biomolecules that may be analyzed include but are not limited to cell proliferation analysis, live/dead cell discrimination, cell cycle analysis, basic phenotyping, immunophenotyping, rare-event detection, apoptosis, phagocytosis, pinocytosis, detection of phosphoproteins, detection of one or more cellular markers, detection of one or more intracellular marker, detection of cancer cells, detection of pathological markers on a cell, microbial cell analysis and/or picophytoplankton analysis. | 05-29-2014 |
20140261721 | System and Method for Acoustic Focusing Hardware and Implementations - The present invention is a method and apparatus for acoustic focusing hardware and implementations. | 09-18-2014 |
20150053561 | Particle Analyzing Systems and Methods Using Acoustic Radiation Pressure - The present invention comprises methods and systems that use acoustic radiation pressure. | 02-26-2015 |