Patent application number | Description | Published |
20090073456 | APPARATUSES, SYSTEMS, AND METHODS FOR LOW-COHERENCE INTERFEROMETRY (LCI) - Embodiments described herein involve low-coherence interferometry (LCI) techniques which enable acquisition of structural and depth information regarding a sample of interest. In one embodiment, a “swept-source” (SS) light source is used in LCI to obtain structural and depth information about a sample. The swept-source light source can be used to generate a reference signal and a signal directed towards a sample. Light scattered from the sample is returned as a result and mixed with the reference signal to achieve interference and thus provide structural information regarding the sample. Depth information about the sample can be obtained using Fourier domain concepts as well as time domain techniques. Several LCI embodiments employing a swept-source light source are disclosed herein. In another embodiment disclosed herein, an a/LCI system and method is provided that is based on a time domain system and employs a broadband light source. The systems and processes disclosed herein can be used for biomedical applications, including measuring cellular morphology in tissues and in vitro as well as diagnosing intraepithelial neoplasia, and assessing the efficacy of chemopreventive and chemotherapeutic agents. | 03-19-2009 |
20090177094 | SYSTEMS AND METHODS FOR TISSUE EXAMINATION, DIAGNOSTIC, TREATMENT, AND/OR MONITORING - Procedures, techniques, and systems for in vivo monitoring, diagnosis, and treatment of tissue during the same or concomitant medical procedure. In disclosed embodiments, during a same or concomitant procedure or examination, tissue can be scanned on a localized level using a real-time optical biopsy system. The real-time optical biopsy system may involve angle-resolved and/or Fourier domain low coherence interferometry (LCI). Because the scanning can be performed in real-time, diagnosis can also be performed in real-time and during the same or concomitant medical procedure. As a result, therapy, if needed, can also be administered to the tissue during the same or concomitant medical procedure. Monitoring of the tissue after therapy can be performed during the same or subsequent procedure. Thus, the procedures and techniques disclosed herein allow detection of tissue anomalies during a first procedure on the patient without waiting for untimely biopsy results, thus providing earlier anomaly detection and treatment and potentially better and timely results and at a lower cost. | 07-09-2009 |
20100014090 | SYSTEMS AND METHODS FOR ENDOSCOPIC ANGLE-RESOLVED LOW COHERENCE INTERFEROMETRY - Fourier domain a/LCI (faLCI) system and method which enables in vivo data acquisition at rapid rates using a single scan. Angle-resolved and depth-resolved spectra information is obtained with one scan. The reference arm can remain fixed with respect to the sample due to only one scan required. A reference signal and a reflected sample signal are cross-correlated and dispersed at a multitude of reflected angles off of the sample, thereby representing reflections from a multitude of points on the sample at the same time in parallel. Information about all depths of the sample at each of the multitude of different points on the sample can be obtained with one scan on the order of approximately 40 milliseconds. From the spatial, cross-correlated reference signal, structural (size) information can also be obtained using techniques that allow size information of scatterers to be obtained from angle-resolved data. | 01-21-2010 |
20100094135 | SYSTEMS AND METHODS FOR PHASE MEASUREMENTS - Preferred embodiments of the present invention are directed to systems for phase measurement which address the problem of phase noise using combinations of a number of strategies including, but not limited to, common-path interferometry, phase referencing, active stabilization and differential measurement. Embodiment are directed to optical devices for imaging small biological objects with light. These embodiments can be applied to the fields of, for example, cellular physiology and neuroscience. These preferred embodiments are based on principles of phase measurements and imaging technologies. The scientific motivation for using phase measurements and imaging technologies is derived from, for example, cellular biology at the sub-micron level which can include, without limitation, imaging origins of dysplasia, cellular communication, neuronal transmission and implementation of the genetic code. The structure and dynamics of sub-cellular constituents cannot be currently studied in their native state using the existing methods and technologies including, for example, x-ray and neutron scattering. In contrast, light based techniques with nanometer resolution enable the cellular machinery to be studied in its native state. Thus, preferred embodiments of the present invention include systems based on principles of interferometry and/or phase measurements and are used to study cellular physiology. These systems include principles of low coherence interferometry (LCI) using optical interferometers to measure phase, or light scattering spectroscopy (LSS) wherein interference within the cellular components themselves is used, or in the alternative the principles of LCI and LSS can be combined to result in systems of the present invention. | 04-15-2010 |
20110157596 | SYSTEMS AND METHODS FOR ENDOSCOPIC ANGLE-RESOLVED LOW COHERENCE INTERFEROMETRY - Fourier domain a/LCI (faLCI) system and method which enables in vivo data acquisition at rapid rates using a single scan. Angle-resolved and depth-resolved spectra information is obtained with one scan. The reference arm can remain fixed with respect to the sample due to only one scan required. A reference signal and a reflected sample signal are cross-correlated and dispersed at a multitude of reflected angles off of the sample, thereby representing reflections from a multitude of points on the sample at the same time in parallel. Information about all depths of the sample at each of the multitude of different points on the sample can be obtained with one scan on the order of approximately 40 milliseconds. From the spatial, cross-correlated reference signal, structural (size) information can also be obtained using techniques that allow size information of scatterers to be obtained from angle-resolved data. | 06-30-2011 |
20110242543 | INTERFEROMETRIC SYSTEMS HAVING REFLECTIVE CHAMBERS AND RELATED METHODS - Disclosed herein are interferometric systems having reflective chambers and related methods. According to an aspect, an interferometric system may include a light source for generating an illumination beam that propagates towards a sample. A sample holder may hold the sample and include a partially reflective cover for allowing a first portion of the illumination beam to pass therethrough to interact with the sample to produce a sample beam that propagates substantially along an optical axis. The cover may be oriented at an angle for reflecting a second portion of the illumination beam to produce a reference beam that propagates at a predetermined angle with respect to the optical axis. An imaging module may redirect the reference beam towards the optical axis at a detection plane. A detector may intercept the sample and reference beams and may generate a holographic representation of the sample based on the beams. | 10-06-2011 |
20120127475 | APPARATUSES, SYSTEMS, AND METHODS FOR LOW-COHERENCE INTERFEROMETRY (LCI) - Low-coherence interferometry (LCI) techniques enable acquisition of structural and depth information of a sample. A “swept-source” (SS) light source may be used. The swept-source light source can be used to generate a reference signal and a signal directed towards a sample. Light scattered from the sample is returned as a result and mixed with the reference signal to achieve interference and thus provide structural information regarding the sample. Depth information about the sample can be obtained using Fourier domain concepts as well as time domain techniques. In another embodiment, an a/LCI system and method is provided that is based on a time domain system and employs a broadband light source. The systems and processes disclosed herein can be used for biomedical applications, included measuring cellular morphology in tissues and in vitro, as well as diagnosing intraepithelial neoplasia, and assessing the efficacy of chemopreventive and chemotherapeutic agents. | 05-24-2012 |
20120281224 | SYSTEMS AND METHODS FOR ENDOSCOPIC ANGLE-RESOLVED LOW COHERENCE INTERFEROMETRY - Fourier domain a/LCI (faLCI) system and method which enables in vivo data acquisition at rapid rates using a single scan. Angle-resolved and depth resolved spectra information is obtained with one scan. The reference arm can remain fixed with respect to the sample due to only one scan required. A reference signal and a reflected sample signal are cross-correlated and dispersed at a multitude of reflected angles off of the sample, thereby representing reflections from a multitude of points on the sample at the same time in parallel. Information about all depths of the sample at each of the multitude of different points on the sample can be obtained with one scan on the order of approximately 40 milliseconds. From the spatial, cross-correlated reference signal, structural (size) information can also be obtained using techniques that allow size information of scatterers to be obtained from angle-resolved data. | 11-08-2012 |
20130128264 | SINGLE-MODE OPTICAL FIBER-BASED ANGLE-RESOLVED LOW COHERENCE INTERFEROMETRIC (LCI)(A/LCI) AND NON-INTERFEROMETRIC SYSTEMS AND METHODS - Optical fiber-based angle-resolved low coherence interferometric systems and methods are disclosed for imaging of scattering samples and measurement of optical and structural properties. A single-mode collection optical fiber can be employed and scanned to collect an angular scattering distribution of scattered light from the sample. Use of a single-mode collection optical fiber can reduce cost, increase signal accuracy, and provide compatibility with optical coherence tomography systems, as examples. In certain embodiments, collected angular scatterings of light from the sample are cross-correlated with a reference signal to provide an angular scattering distribution of scattering of light from the sample. The angular scattering distribution can be spectrally dispersed to yield an angle-resolved, spectrally-resolved cross-correlation profile having depth-resolved information about the sample at the scattering angles. The angle-resolved, spectrally-resolved cross-correlation profile can be analyzed to provide size and/or depth information about the sample. The systems and methods can also be employed in non-interferometric modes. | 05-23-2013 |
20130135614 | DUAL WINDOW PROCESSING SCHEMES FOR SPECTROSCOPIC OPTICAL COHERENCE TOMOGRAPHY (OCT) AND FOURIER DOMAIN LOW COHERENCE INTERFEROMETRY - Current apparatuses and methods for analysis of spectroscopic optical coherence tomography (SOCT) signals suffer from an inherent tradeoff between time (depth) and frequency (wavelength) resolution. In one non-limiting embodiment, multiple or dual window (DW) apparatuses and methods for reconstructing time-frequency distributions (TFDs) that applies two windows that independently determine the optical and temporal resolution is provided. For example, optical resolution may relate to scattering information about a sample, and temporal resolution may be related to absorption or depth related information. The effectiveness of the apparatuses and methods is demonstrated in simulations and in processing of measured OCT signals that contain fields which vary in time and frequency. The DW technique may yield TFDs that maintain high spectral and temporal resolution and are free from the artifacts and limitations commonly observed with other processing methods. | 05-30-2013 |
20130176560 | DUAL WINDOW PROCESSING SCHEMES FOR SPECTROSCOPIC OPTICAL COHERENCE TOMOGRAPHY (OCT) AND FOURIER DOMAIN LOW COHERENCE INTERFEROMETRY - Current apparatuses and methods for analysis of spectroscopic optical coherence tomography (SOCT) signals suffer from an inherent tradeoff between time (depth) and frequency (wavelength) resolution. In one non-limiting embodiment, multiple or dual window (DW) apparatuses and methods for reconstructing time-frequency distributions (TFDs) that applies two windows that independently determine the optical and temporal resolution is provided. For example, optical resolution may relate to scattering information about a sample, and temporal resolution may be related to absorption or depth related information. The effectiveness of the apparatuses and methods is demonstrated in simulations and in processing of measured OCT signals that contain fields which vary in time and frequency. The DW technique may yield TFDs that maintain high spectral and temporal resolution and are free from the artifacts and limitations commonly observed with other processing methods. | 07-11-2013 |
20130265582 | SYSTEMS AND METHODS FOR ENDOSCOPIC ANGLE-RESOLVED LOW COHERENCE INTERFEROMETRY - Fourier domain a/LCI (faLCI) system and method which enables in vivo data acquisition at rapid rates using a single scan. Angle-resolved and depth resolved spectra information is obtained with one scan. The reference arm can remain fixed with respect to the sample due to only one scan required. A reference signal and a reflected sample signal are cross-correlated and dispersed at a multitude of reflected angles off of the sample, thereby representing reflections from a multitude of points on the sample at the same time in parallel. Information about all depths of the sample at each of the multitude of different points on the sample can be obtained with one scan on the order of approximately 40 milliseconds. From the spatial, cross-correlated reference signal, structural (size) information can also be obtained using techniques that allow size information of scatterers to be obtained from angle-resolved data. | 10-10-2013 |
20130265585 | SYSTEMS AND METHODS FOR PHASE MEASUREMENTS - Preferred embodiments of the present invention are directed to systems for phase measurement such as for imaging small biological objects with light. These embodiments can be applied to the fields of, for example, cellular physiology and neuroscience. These preferred embodiments are based on principles of phase measurements and imaging technologies. The scientific motivation for using phase measurements and imaging technologies is derived from, for example, cellular biology at the sub-micron level which can include, without limitation, imaging origins of dysplasia, cellular communication, neuronal transmission and implementation of the genetic code. Light based techniques with nanometer resolution enable the cellular machinery to be studied in its native state. Thus, preferred embodiments of the present invention include systems based on principles of interferometry and/or phase measurements and are used to study cellular physiology. These systems include principles of low coherence interferometry (LCI) using optical interferometers to measure phase, or light scattering spectroscopy (LSS) wherein interference within the cellular components themselves is used, or in the alternative the principles of LCI and LSS can be combined to result in systems of the present invention. | 10-10-2013 |
20150045677 | SYSTEMS AND METHODS FOR ENDOSCOPIC ANGLE-RESOLVED LOW COHERENCE INTERFEROMETRY - A method of assessing tissue health comprises the steps of obtaining depth-resolved spectra of a selected area of in vivo tissue, and assessing the health of the selected area based on the depth-resolved structural information of the scatterers. Obtaining depth-resolved spectra of the selected area comprises directing a sample beam towards the selected area at an angle, and receiving an angle-resolved scattered sample beam. The angle-resolved scattered sample beam is cross-correlated with the reference beam to produce an angle-resolved cross-correlated signal about the selected area, which is spectrally dispersed to yield an angle-resolved, spectrally-resolved cross-correlation profile having depth-resolved information about the selected area. The angle-resolved, spectrally-resolved cross-correlation profile is processed to obtain depth-resolved information about scatterers in the selected area. | 02-12-2015 |
20150062591 | APPARATUSES, SYSTEMS, AND METHODS FOR LOW-COHERENCE INTERFEROMETRY (LCI) - Embodiments described herein involve low-coherence interferometry (LCI) techniques which enable acquisition of structural and depth information regarding a sample of interest. In one embodiment, a “swept-source” (SS) light source is used in LCI to obtain structural and depth information about a sample. The swept-source light source can be used to generate a reference signal and a signal directed towards a sample. Light scattered from the sample is returned as a result and mixed with the reference signal to achieve interference and thus provide structural information regarding the sample. Depth information about the sample can be obtained using Fourier domain concepts as well as time domain techniques. Several LCI embodiments employing a swept-source light source are disclosed herein. In another embodiment disclosed herein, an a/LCI system and method is provided that is based on a time domain system and employs a broadband light source. The systems and processes disclosed herein can be used for biomedical applications, including measuring cellular morphology in tissues and in vitro as well as diagnosing intraepithelial neoplasia, and assessing the efficacy of chemopreventive and chemotherapeutic agents. | 03-05-2015 |