Background/Objectives: The subject of the submitted article lies within the scope of the heightened interest for magnetostriction. This interest demonstrates itself through the idea of combining opposite effects in one device, whereas straintronics is on the forefront. Methods/Statistical analysis: An extended report is made on resonant-type and non-resonant magnetoelastic transducers, and within the first group actuators employing the effect of magnetic tunnel junction, cantilevers, sensors of mechanical quantities, and high-frequency sensors are dwelt upon. Findings: The paper offers a review of principal results of use of direct and reverse magnetoelastic effects in the development of straintronic devices. The author undertakes a detailed investigation into the structure and principles of functioning of different types of strainmeters. Actual and possible instances of their practical application are outlined, where biomedical use as most promising is paid particular attention.

Basantkumar, R., Stadler B.H., Robbins, W. & Summers, E. (2006). Integration of Thin-Film Galfenol With MEMS Cantilevers for Magnetic Actuation. IEEE Transactions on Magnetics, 42(10), 3102-3104.

Belov, K.P. (1987). Magnetostriction effects and their technical application. Moscow: Nauka, 266 p.

Belov, K.P., Levitin, R.Z. & Nikitin, S.A. (1961). Physics of metals and metal studies, Moscow: Nauka, 348 p.

Biswas, A., Atulasimha, J. & Bandyopadhyay, S.  (2014). An errow-resilient non-volatilemagnetoelastic universal logic gate with ultralow energy-delay product. Scientific Reports, 3, 1-7.

Butera, A., Gómez, J., Weston, J.L. & Barnard, J.A. (2005). Growth and magnetic characterization of epitaxial Fe81Ga19/MgO (100) thin films. J. Appl. Phys., 98(3), 339-351.

Chorits, L., Koynov, K., Renieri, G. & Barton, K. (2010). Surface topographies of glaucoma drainage devices and humaintenonfibrablast adhesion. Invest Ophthamol, 51(8), 4047-4053.

Clark, A.E, Hathaway, K.B., Wun-Fogle, M., Restorff, J.B., Lograsso, T.A, Keppens, V.M, Petculescu, G. & Taylor, R.A. (2003). Extraordinary magnetoelasticity and lattice softening in bcc Fe–Ga alloys. J. Appl. Phys., 93, 8621.

Croh, J., Cros, F. & Courcimault, C. (2012). Strain monitoring system and apparature. USA patent. N. 8278941.

Fazir, T.A. (2012). FeGa based tunneling magnetoresistance junctions and strain sensors. Direct access: www.tu-ilmenau.de/fileadmin/media/mms/Aktuelles/IMN_Report_2013_small.pdf.

Grims, C.A., Roy, S.C., Rany, S. & Cay, Q. (2011). Theory, Instrumentations and Applications of magnetoelastic Resonance Sensors: A Review. Sensors, 11, 2809-2844.

Grünberg, P. (1986). Layered Magnetic Structures: Evidence for Antiferromagnetic Coupling of Fe Layers across Cr Interlayers. Phys. Rev. Lett., 57, 2442-2445.

Handbook of modern sensors: physics, designs, and applications. (2010). New York: Springer-Verlag: 437 p.

Herzer, G. (1992). Nanocrystalline soft magnetic materials. Journal of magnetism and magnetic materials, 112, 258–262.

Hunter, D., Osborn, W., Wang, K., Kazantseva, N. (2011). Giant magnetostriction in annealed Co1 − xFex thin-films. Direct access: http://www.nature.com/articles/ncomms1529

Jack, H.G., Record, P., Shang, X. & Wlodarczykat, K. (2015). Optimised co-electrodeposition of Fe–Ga alloys for maximum magnetostriction effect. Sensor sand Actuators, 223, 91–96.

Joule, J.P. (1842). On a new Class of Magnetic Forces. Sturgeon’s Annals of Electricity, 8, 219.

Joule, J.P. (1884). Scientific Papers. London: Taylor and Francin, 367 p.

Koon, N., Schinder, A. & Carter, F. (1971). Giant magnetostriction in cubic rare earth-iron compounds of the type RFe2. Physics Letters A, 37(5), 413–414.

Lakshmanan, R.S. (2008).  Phage-based magnetoelastic sensor for the detection of Salmonella Typhimurium. Direct access: etd.auburn.edu/bitstream/.../Lakshmanan_Ramji_26.pdf

Löhndorf, M., Bootsmann, M.T., Borowski, R., Dokupil, S. & Hout, J. (2004). Magnos: Magnetic-MEMS. Center of advanced european studies and research. Annual Report, 1, 78-79.

Pepakayala, V. (2015). Micromachened Magnitoelastic Sensors and Actuators for Biomedical Devices and Other Applications: PhD Thesis. Univer. Michigan, 252 p.

Pereles, B.D. (2014). Design and Applications of wireless passive magnetowlastic resonance and magnetoharmonicforсe sensors: PhD Thesis. Michigan: Michigan Unver. Technol, 197 p.

Quandt, E., Dokupil, S., Bootsmann,  M.T. & Stein, S. (2004a). Magnos: GMR/TMR Strain Sensors. Center of advanced european studies and research. Annual Report, 3, 82-83.

Quandt, E., Frommberger, M., Glasmachers, S., Gorski, R., Schmutz, C. & Tewes, M. (2004b). MURI: Strain Dependence of a Remote Interrogatable Sensor Based on Magnetostrictive Thin Films. Center of advanced european studies and research. Annual Report, 3, 84-85.

Quandt, E., Stein, S. & Wuttig, M. (2007). MURI: Composite Magnetoelectric Effect for Magnetic Field Sensing. Center of advanced European studies and research. Annual Report, 2, 88-89.

Wang, B.W. (2008). Structure, magnetic properties and magnetostriction of Fe81Ga19 thin films. Journal of Magnetism and Magnetic Materials, 320(5), 769–773.

Wang, D., Norman, C., Qian, Z. & Daughton, J.M. (2004). 70% TMR at room temterature for sandwich Tunnel Junctions with CoFeB as free and pinned layers. IEEE Trans. Magn, 40, 22-69.

Wilson, C. (2007). New Materials for Micro-scale Sensors and Actuators. An engineering Review. Materials science & engineering, 56, 1-129;

Ying, Y., Qingfeng, Z., Jinwu, W., Jianbo, W., Guohong, D., Zhenghu, Z., Xiaoshan, Z., Yiwei, L., Huali, Y., Yao, Z., Shuhong, X., Baomin, W. & Run-Wei, L. (2015). Static and high frequency magnetic properties of FeGa thin films deposited on convex flexible substrates. Applied physics letters, 106, 162-185.