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limits of the assumptions that have been presented—the relevance of BCVI to gener-
ate a metrics for the dynamics of the brachial arterial flow is clearly sustained. As pre-
sented, its time derivative enables the assessment of several important hemodynamic
indices, and it may be inferred that BCVI may be a relevant, useful, easily accessible
cardiovascular monitoring technique, which may be complemented by the blood pres-
sure monitoring, using a unique apparatus.
References
Ahmad, S., Batkin, I., Kelly, O., Dajani, H.R., Bolic, M., Groza, V., 2013. Multiparameter physiological analysis
in obstructive sleep apnea simulated with maneuver. IEEE Trans. Instrum. Meas. 62 (10), 2751 2762.
Alexander, F.A., Price, D.T., Bhansali, S., 2013. From cellular cultures to cellular spheroids: is impedance
spectroscopy a viable tool for monitoring multicellular spheroid (MCS) drug models? IEEE Rev.
Biomed. Eng. 6, 63 76.
Al-Surkhi O.I., Riu P.J., Vazquez F.F., Ibeas J., 2007. Monitoring Cole Cole parameters during haemo-
dialysis (HD). In: Proceedings of the 2007 29th Annual International Conference of the IEEE
Engineering in Medicine and Biology Society, Lyon, France, pp. 2238 2241, August 2007.
Amini, M., Hisdal, J., Kalvøy, H., 2018. Applications of bioimpedance measurement techniques in tissue
engineering. J. Electric Bioimp. 9, 142 158.
Andreuccetti, D., Fossi, R., Petrucci, C., 1997. An Internet Resource for the Calculation of the Dielectric
Properties of Body Tissues in the Frequency Range 10 Hz 100 GHz. IFAC-CNR, Florence (Italy),
Based on data published by C. Gabriel et al. in 1996. ,http://niremf.ifac.cnr.it/tissprop.. (accessed 30
January, 2015).
Bejan, A., 1993. Heat Transfer. Wiley, New York, pp. 295 298.
Bera, T.K., 2014. Bioelectrical impedance methods for noninvasive health monitoring: a review. J. Med.
Eng. Article ID 381251, 28 pages.
Bernstein, D.P., 2010. Impedance cardiography: Pulsatile blood flow and the biophysical and electrody-
namic basis for the stroke volume equations. J. Electric. Bioimp. 1 (1), 2 17.
Bernstein, D.P., Henry, I.C., Lemmens, H.J., Chaltas, J.L., DeMaria, A.N. Moon, J.B., et al., , 2015.
Validation of stroke volume and cardiac output by electrical interrogation of the brachial artery in
normals: assessment of strengths, limitations, and sources of error, J Clin Monit Comput 29 (6),
789 800.
Bernstein D.P., Osypka M.J., Apparatus and method for determining an approximation of stroke volume and car-
diac output of the heart, US Patent No. 6,511,438, Jan. 28, 2003, https://patentimages.storage.google-
apis.com/d4/a5/57/351bc704baed48/US6511438.pdf.
Bhardwaja, P., Raia, D.V., Garga, M.L., Mohanty, B.P., 2018. Potential of electrical impedance spectros-
copy to differentiate between healthy and osteopenic bone. Clin. Biomech. 57, 81 88.
Buendi, R., Seoane, F., Bosaeus, I., Gil-Pita, R., Johannsson, G., Ellegård, L., et al., 2014. Robustness
study of the different immittance spectra and frequency ranges in bioimpedance spectroscopy analysis
for assessment of total body composition. Physiol. Meas. 35 (7), 1373 1395.
Chandran, K.B., 2001. Chapter 5: Flow Dynamics in the Human Aorta: Techniques and Applications,in
Cardiovascular Techniques, II. CRC Press LLC.
Choudari P., Panse M.S., 2013. Measurement of cardiac output using bioimpedance method. In:
International Conference on Communication Technology 2013, Guilin, China, pp. 28 33. IJCATM:
www.ijcaonline.org.
Cicho˙ z-Lach, H., Michalak, A., 2017. A comprehensive review of bioelectrical impedance analysis and
other methods in the assessment of nutritional status in patients with liver cirrhosis, Hindawi.
Gastroenterol. Res. Pract. 2017, Article ID 6765856, 10.
