Method and apparatus for measurement and imaging of tissue compressibility or compliance

Patent 5107837 Issued on April 28, 1992. Estimated Expiration Date:

June 8, 2010. Estimated Expiration Date is calculated based on simple USPTO term provisions. It does not account for terminal disclaimers, term adjustments, failure to pay maintenance fees, or other factors which might affect the term of a patent.

Abstract Claims Description Full Text

Patent References

Multi-beam tracking for angle error correction in speed of sound estimations
Patent #: 4878500
Issued on: 11/07/1989
Inventor: Ophir, et al.

Ultrasound method and apparatus for evaluating, in vivo, bone conditions
Patent #: 4913157
Issued on: 04/03/1990
Inventor: Pratt, Jr., et al.

Method and device for acoustic testing of elasticity of biological tissues
Patent #: 4947851
Issued on: 08/14/1990
Inventor: Sarvazyan, et al.

Method and apparatus for the measurement of bone quality in vivo Patent #: 4976267
Issued on: 12/11/1990
Inventor: Jeffcott, et al.

Inventors

Assignee

Board of Regents, University of Texas System

Application

No. 535312 filed on 06/08/1990

US Classes:

600/437Ultrasonic

Examiners

Primary: Jaworski, Francis J.

Attorney, Agent or Firm

Arnold, White & Durkee

International Class

A61B 008/00

Abstract

An improved ultrasonic pulse-echo method and apparatus that has particular application in making precision measurements of compressibility in any backscattering material, in particular organic tissue, is disclosed. The method employs a standard transducer or transducer containing device which is translated transaxially, thereby compressing or displacing a proximal region of a target body in small known increments. At each increment, a pulse is emitted and an echo sequence (A-line) is detected from regions within the target along the sonic travel path or beam of the transducer. Resulting time shifts in echo segments corresponding to features in the target provide relative and quantitative information concerning compressibility of the target.

Other References

Saada, Elasticity, Theory and Applications, Ch. 14. (Pergamon Press, NY, 1974)
Van Pelt, Subtle Tumors Found with New Ultrasound, Insight, May 14, 1990 p. 45
Levinson, Ultrasound Propagation in Anisotropic Soft Tissues: The Application of Linear Elastic Theory, J. Biomech 20, 251-260 (1987)
Yamokoshi et al., Ultrasonic imaging of itnernal vibration of soft tissue under foced vibration, Proc. Sec. Joint Mtg. of ASA and ASJ, Nov., 1988 (Abstract RR-12)
Boucher et al., Analysis of discrete implementation of generalized cross correlator, IEEE Trans. Acoust., Speech and Sig. Proc. ASSP-29, 609-611 (1981)
Ophir, et al., Elimination of Diffraction error in acoustic attenuation estimation via axial beam translation, Ultrasonic Imaging 10, 139-152 (1988)
Pozniak, et al., Clinical Efficacy of Kitecko Ultrasonic Conductor, Investigative Radiology 24, 128-132 (1989)
Goodman, some fundamental properties of speckle, J. Opt. Soc. Am. 66, 1145-1150 (1976)
Kossoff, et al., A sonographic technique to reduce beam distortion by curved interfaces, Ultrasound Med. Biol. 15, 375-382 (1989)
Eisensher, et al., La Palpation Echographique Rythmec-Echosismographie, Journal de Radiologie 64, 255-261 (1983)
Saada, Elasticity, Theory and Applications, Ch. 14, (Pergamon Press, NY, 1974)
Lerner, et al., Sono elasticity in ultrasonic tissue characteriszation and echographic imaging, in Proc. 7th Eur. Comm. Workshop, J. M. Thijssen, ed. Oct. 1987, Nijmegen, The Netherlands
Levinson, The Ultrasonic Investigation of Dynamic Muscle Elasticity in Vivo, Abstracts of presentations for the American Institute of Ultrasound in Medicine Proceedings, J. Ultrasound Med., Oct. 1988, Abstract #2005
Hill, et al., Ultrasound Remote Palpation (URP): Use of Shear Elastic Modulus to Differentiate Pathology, J. Ultrasound Med, Oct. 1988, Abstract #2013
Yagi et al., Local Displacement Analysis of Inhomogeneous Soft Tissue by Spatial Correlation of RF Echo Signals, J Ultrasound Med., 1988, Abstract #2028
Krouskop, et al., Measurement of Stiffness of Soft Tissue Using an Ultrasonic Perturbator, Conference Abstract, Houston Society for Engineering in Medicine and Biology, Feb. 1990, p. 94
Lerner, et al., Detection of Hard Tumors By Sonoelasticity Imaging: Initial Results, Abstracts, Ultrasonic Imaging and Tissue Characterization Symposium, p. 139 1990
Gore et al., Dynamic Autocorrelation Analysis of A scans in vivo, Ultrasonic Tissue Characterization II, M. Linzer, ed. NBS, Spec. Publ. 525, pp. 275-280 (U.S. Government Printing Office, Washington, D.C., 1979)
Chu and Raeside, Fourier analysis of the echo-cardiogram, Phys. Med. Biol. 23, 100-105 (1978)
Krouskop et al., A pulsed Doppler ultrasonic system for making noninvasive measurements of the mechanical properties of soft tissue, J. Rehabil. Res. Dev. 24, 1-8 (1987)
Lerner et al., "Sono-elasticity" images derived from Ultrasound signals in mechanically vibrated tissues, Ultrasound Med. Biol. 16, 231-239 (1990)
Tristam, et al., Ultrasonic Study of in vivo kinetic characteristics of human tissues, Ultrasound Med. Biol. 12, 927-937 (1986)
Dickinson and Hill, Measurement of soft tissue motion using correlation between A scans, Ultrasound Med. Biol. 8, 263-271 (1982)
Wilson and Robinson, Ultrasonic measurement of small displacements and deformations of tissues
The U.S. Government may own rights in this application and patents that may issue therefrom, pursuant to NIH Grants CA 38515 and CA 4438