In the 1970s and 1980s, in parallel with the studies of soft tissue biomechanics, he developed ultrasonic devices for the investigation of biomolecular interactions and obtained significant results on thermodynamic characteristics of water in the hydration shell of proteins and nucleic acids.[3][4][5]
He continued these studies on the hydration of biopolymers at the Laboratory of Biomolecular Acoustics, which he organized at Rutgers University, NJ, US in 1992.[6]
Beginning in the late 80s, a significant part of Sarvazyan's research activities were on the problems of elastography, an emerging technology of medical diagnostics. In 1991–1992, in collaboration with the University of Michigan, Ann Arbor, Sarvazyan conducted pioneering experiments on MRI and ultrasonic elastography.[7][8][9] He published several review papers on biophysical basis of elasticity imaging, on soft tissue biomechanics and on acoustical radiation force, which is currently the key component in the majority of elasticity imaging technologies and devices.[10][11][12][13][14]
During last decade, most of his research activities and publications were on the various medical applications a branch of elastography called mechanical imaging (a.k.a. tactile imaging), developed by Sarvazyan with Vladimir Egorov.[15][16][17]
Sarvazyan has published over 200 research papers and book chapters, and edited 6 books. He has been the Principal Investigator of over 30 research projects funded by NIH, NASA, DoD and Bill and Melinda Gates Foundation. He has over 100 U.S. and international patents and invention certificates.[18]
Sarvazyan is the co-founder of several companies specializing in elastography: ProUroCare Medical Inc. (Golden Valley, MN, 1999), Medical Tactile, Inc. (Los Angeles, CA, 2000), SuperSonic Imagine (Aix-en-Province, France, 2005) and Advanced Tactile Imaging, Inc. (Trenton, NJ, 2013).[19] He is also the founder of Artann Laboratories Inc.[20]
^Buckin VA, Sarvazyan AP, Kharakoz DP. Water near biological molecules. A review. - In: Water in Disperse Systems. Ed. Deryagin BV, Churaev NV, Ovcharenko D, Moscow, Publ. Chemistry, (in Russian), 1989, 45-63.
^Fowlkes J, Emelianov S, Pipe J, Carson P, Adler R, Sarvazyan A, Skovoroda A. Possibility of cancer detection through measurement of elasticity properties. Radiology 1992; 185(P): 206-207.
^Sarvazyan AP, Skovoroda AR, Emelianov SY, Fowlkes JB, Pipe JG, Adler RS, Buxton RB, Carson PL. Biophysical bases of elasticity imaging. In: Acoustical Imaging. Ed. Jones JP, Plenum Press, New York and London, 1995; 21: 223-240.
^Sarvazyan AP. Elastic properties of soft tissues. In: Handbook of Elastic Properties of Solids, Liquids and Gases, Volume III, Chapter 5, eds. Levy M, Bass HE and Stern RR, Academic Press, New York 2001, 107-127.
^Sarvazyan A, Hill CR. Physical chemistry of the ultrasound-tissue interaction. In: Physical Principles of Medical Ultrasonics. 2nd ed. Chichester: John Wiley, Chapter 7, eds. Hill CR, Bamber JC, ter Haar GR, 2004, 223-235. doi:10.1002/0470093978.ch7
^Sarvazyan A. Diversity of biomedical applications of acoustic radiation force. Review. Ultrasonics 2010, 50(2):230-4. doi:10.1016/j.ultras.2009.10.001
^Sarvazyan A, Hall TJ, Urban MW, Fatemi M, Aglyamov SR, Garra BS. An overview of Elastography–an emerging branch of medical imaging. Current Medical Imaging Reviews, 2011, 7(4):255-282. PMC3269947