He-Ne Laser Imaging Probes Premature Diabetes Mellitus
International Journal of Biomedical Materials Research
Volume 3, Issue 2, April 2015, Pages: 14-18
Received: Oct. 20, 2013;
Accepted: Jun. 24, 2015;
Published: Jun. 25, 2015
Views 4035 Downloads 136
Alok Singh, Department of Physics, PSIT College of Engineering, Kanpur, Uttar Pradesh, India
Savita Singh, Department of Physics, PSIT College of Engineering, Kanpur, Uttar Pradesh, India
Pradeep Kumar Singh, Department of Mathematics, PSIT College of Engineering, Kanpur, Uttar Pradesh, India
N. S. Parmar, Department of Mechanical Engineering, PSIT College of Engineering, Kanpu, Uttar Pradesh, India
Neetu Singh, Department of Chemistry, PSIT College of Engineering, Kanpur, Uttar Pradesh, India
Follow on us
An empirical approach to develop a comprehensive monitoring framework to track progress of ballistic photons through glucose doped aqueous humor by two dimensional sixteen Mueller polarization matrix element images for deepening efforts in polarimetry reported. The glucose doped aqueous humor has been illuminated with a He-Ne (632.8 nm) laser in vitro measurement. The obtained transmitted Mueller polarization matrix images are strong evidence to discriminate normal glucose level, impaired fasting glycaemia (IFG), impaired glucose tolerance (IGT) and diabetes mellitus.
Polarimeter, Mueller Polarization Matrix, Aqueous Humor
To cite this article
Pradeep Kumar Singh,
N. S. Parmar,
He-Ne Laser Imaging Probes Premature Diabetes Mellitus, International Journal of Biomedical Materials Research.
Vol. 3, No. 2,
2015, pp. 14-18.
The Diabetes control and complications trial research group. “The effect of intensive treatment of diabetes on the development and progression of long-term complication in insulin-dependent diabetes mellitus.” N Engl J Med.; 329(14): 977-86 (1993).
The diabetes control and complications trial research group. “Life time benefits and costs of intensive therapy as practiced in the diabetes control and complications trial.” JAMA; 276(17):1409-15 (1996).
DC. Klonoff, “Non-invasive blood glucose monitoring” Diabetes Care; 20(3):433-7 (1997).
HM Heise , “Non-invasive monitoring of metabolites using near infrared spectroscopy: state of the art.“ Horm Metab Res.; 28(10):527-34 (1996).
Andrea Tura, Alberto Maran, Giovanni Pacini ,“Non-invasive glucose monitoring: Assessment of technologies and devices according to quantitative criteria.“ Diabetes Research and Clinical Practice; 77(1):16-40 (2007)
MR Robinson, RP Eaton, DM Haaland et al, “Nonivasive glucose monitoring in diabetic patients: a preliminary evaluation.” Clinical Chemistry; 38(9): 1618-1622 (1992).
McNichols, Roger J., and Gerard L. Cote, "Optical glucose sensing in biological fluids: an overview." Journal of Biomedical Optics; 5(1): 5-16 (2000).
Goldstein, Dennis H, “Mueller matrix dual-rotating retarder polarimeter.” Applied Optics; 31(31):6676-6683, (1992).
J.M. Schmitt, A.H. Gandjbakhche, and R.F. Bonner, “Use of polarized light to discriminate short-path photons in a multiply scattering medium.” Applied Optics; 31(30): 6535-6546(1992).
Lide, R. David ,“CRC handbook of physics and chemistry.” The Chemical Rubber Company, Cleveland, OH (2003).
Azzam, R. M. A., N. M. Bashara, and Stanley S. Ballard,“ Ellipsometry and Polarized Light.“ North Holland, (1978).
Jacques, Steven L, "Monte Carlo modeling of light transport in tissue (steady state and time of flight)." Optical-thermal response of laser-irradiated tissue. Springer Netherlands; 109-144 (2011).