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Stephen A Mcaleavey

from Rochester, NY
Age ~50
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Also known as:
Stephen Mc Aleavey, Stephen A Mcalea, Stephen A Mcalavey, Stephen Mc, Stephen V, Stephen Y
Phone and address:
219 Squire Dr, Rochester, NY 14623
Related to:
Kim Harwell, 65Cameron Mcmillin, 40Jessica Mccann, 33Judy L Crosby, 63
Connected to:
Mary M Mcaleavey, 73Shannon C Mcaleavey, 53Joseph J Mcalee, 61Raquel A Mcalee, 43Ryan J Mcalee, 35Anna K Mcaleer, 38Cheree M Mcalees, 60Christina L Mcaleer, 61David G Mcalees, 80Gerard P Mcaleer, 67

Stephen Mcaleavey Phones & Addresses

  • 219 Squire Dr, Rochester, NY 14623
  • 60 Crittenden Rd, Rochester, NY 14620 (585) 442-2347
  • 1880 Crittenden Rd, Rochester, NY 14623
  • 51 Alliance Ave, Rochester, NY 14620 (716) 256-1014
  • 1200 Remington Cir, Durham, NC 27705 (919) 383-5875
  • Bethel, CT

Work

Company: University of rochester Aug 2004 to May 2010 Position: Assistant professor

Education

School / High School: Duke University 2001 to 2004

Skills

Biomedical Engineering • Matlab • Signal Processing • Image Processing • Medical Imaging • Image Analysis

Industries

Higher Education

Resumes

Resumes

Stephen Mcaleavey Photo 1

Associate Professor Of Biomedical Engineering

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Location:
Rochester, NY
Industry:
Higher Education
Work:
University of Rochester Aug 2004 - May 2010
Assistant Professor
University of Rochester Aug 2004 - May 2010
Associate Professor of Biomedical Engineering
Duke University Nov 2001 - Aug 2004
Research Associate
Education:
Duke University 2001 - 2004
University of Rochester 1996 - 2002
Doctorates, Doctor of Philosophy, Electrical Engineering University of Rochester 1992 - 1996
Bachelors, Bachelor of Science, Electrical Engineering
Skills:
Biomedical Engineering
Matlab
Signal Processing
Image Processing
Medical Imaging
Image Analysis

Publications

Us Patents

Shear Modulus Estimation By Application Of Spatially Modulated Impulse Acoustic Radiation Force Approximation

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US Patent:
8225666, Jul 24, 2012
Filed:
May 9, 2008
Appl. No.:
12/118359
Inventors:
Stephen McAleavey - Rochester NY, US
Assignee:
University of Rochester - Rochester NY
International Classification:
G01N 9/24
US Classification:
73602, 73645, 600442
Abstract:
A method for determining a shear modulus of an elastic material with a known density value is provided. In this method, a spatially modulated acoustic radiation force is used to initially generate a disturbance of known spatial frequency or wavelength. The propagation of this initial displacement as a shear wave is measured using ultrasound tracking methods. A temporal frequency is determined based on the shear wave. The shear modulus of the elastic material at the point of excitation may be calculated using the values of the spatial wavelength, material density, and temporal frequency.

Methods, Systems, And Computer Program Products For Imaging Using Virtual Extended Shear Wave Sources

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US Patent:
20040068184, Apr 8, 2004
Filed:
Oct 7, 2002
Appl. No.:
10/266096
Inventors:
Gregg Trahey - Hillsborough NC, US
Kathryn Nightingale - Durham NC, US
Roger Nightingale - Durham NC, US
Stephen McAleavey - Durham NC, US
International Classification:
A61B008/00
US Classification:
600/437000
Abstract:
Ultrasound energy is transmitted into tissue in a first direction to provide a virtual extended shear wave source. The virtual extended shear wave source generates an extended shear wave that propagates in a second direction substantially orthogonal to the first direction to cause movement in the first direction of tissue that is offset from the virtual extended shear wave source in the second direction. Related ultrasound imaging systems and computer program products are also disclosed.

Methods And Systems For Spatially Modulated Ultrasound Radiation Force Imaging

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US Patent:
20110184287, Jul 28, 2011
Filed:
Dec 10, 2010
Appl. No.:
12/965807
Inventors:
Stephen A. McAleavey - Rochester NY, US
International Classification:
A61B 8/00
US Classification:
600438
Abstract:
Methods for determining the shear modulus of a tissue of an individual are disclosed. In one embodiment, an acoustic pulse is transmitted and a reference echo signal is received. A first push pulse is transmitted at a second location of the individual. A second push pulse is transmitted at a third location of the individual. A series of tracking pulses are transmitted at the first location and a tracking echo signal is received from each tracking pulse. The effect of the first and second push pulses on the tissue is determined through analysis of the tracking echo signals. The shear modulus of the tissue is calculated based on the effect of the push pulses on the tissue. A system for imaging a region of tissue is presented.

Shear Modulus Estimation By Application Of Spatially Modulated Impulse Acoustic Radiation Force Approximation

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US Patent:
20130165778, Jun 27, 2013
Filed:
Jul 23, 2012
Appl. No.:
13/556049
Inventors:
Stephen McAleavey - Rochester NY, US
Assignee:
UNIVERSITY OF ROCHESTER - Rochester NY
International Classification:
A61B 8/08
US Classification:
600438
Abstract:
A method for determining a shear modulus of an elastic material with a known density value is provided. In this method, a spatially modulated acoustic radiation force is used to initially generate a disturbance of known spatial frequency or wavelength. The propagation of this initial displacement as a shear wave is measured using ultrasound tracking methods. A temporal frequency is determined based on the shear wave. The shear modulus of the elastic material at the point of excitation may be calculated using the values of the spatial wavelength, material density, and temporal frequency.

Shear-Modulus Estimation By Application Of Spatially Modulated Impulse Acoustic Radiation Force Approximation

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US Patent:
20140180091, Jun 26, 2014
Filed:
Feb 25, 2014
Appl. No.:
14/190078
Inventors:
- Rochester NY, US
Stephen McAleavey - Rochester NY, US
Assignee:
University of Rochester - Rochester NY
International Classification:
A61B 8/08
US Classification:
600438
Abstract:
A method for determining a shear modulus of an elastic material with a known density value is provided. In this method, a spatially modulated acoustic radiation force is used to initially generate a disturbance of known spatial frequency or wavelength. The propagation of this initial displacement as a shear wave is measured using ultrasound tracking methods. A temporal frequency is determined based on the shear wave. The shear modulus of the elastic material at the point of excitation may be calculated using the values of the spatial wavelength, material density, and temporal frequency.
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Stephen A Mcaleavey from Rochester, NY, age ~50 Get Report