Abstract:We present a system capable of measuring the total retinal blood flow using a combination of dual beam Fourier-domain Doppler optical coherence tomography with orthogonal detection planes and a fundus camera-based retinal vessel analyzer. Our results show a high degree of conformity of venous and arterial flows, which corroborates the validity of the measurements. In accordance with Murray's law, the log-log regression coefficient between vessel diameter and blood flow was found to be ~3. The blood's velocity scaled linearly with the vessel diameter at higher diameters (> 60 µm), but showed a clear divergence from the linear dependence at lower diameters. Good agreement with literature data and the large range and high measurement sensitivity point to a high potential for further investigations. 673-800 (1987). 33. J. E. Grunwald, C. E. Riva, J. Baine, and A. J. Brucker, "Total retinal volumetric blood flow rate in diabetic patients with poor glycemic control," Invest. Ophthalmol. Vis. Sci. 33(2), 356-363 (1992). 34. J. E. Grunwald, J. DuPont, and C. E. Riva, "Retinal haemodynamics in patients with early diabetes mellitus," Br.J. Ophthalmol. 80(4), 327-331 (1996). 35. B. Pemp, E. Polska, G. Garhofer, M. Bayerle-Eder, A. Kautzky-Willer, and L. Schmetterer, "Retinal blood flow in type 1 diabetic patients with no or mild diabetic retinopathy during euglycemic clamp," Diabetes Care 33(9), 2038-2042 (2010 562-568 (1931). 39. T. W. Secomb and A. R. Pries, "Blood viscosity in microvessels: Experiment and theory," C. R. Phys. 14(6), 470-478 (2013). 40. E. Logean, L. Schmetterer, and C. E. Riva, "Velocity Profile of Red Blood Cells in Human Retinal Vessels using Confocal Scanning Laser Doppler Velocimetry," Laser Phys. 13, 45-51 (2003). 41. J. P. Garcia, Jr., P. T. Garcia, and R. B. Rosen, "Retinal blood flow in the normal human eye using the canon laser blood flowmeter," Ophthalmic Res. 34(5), 295-299 (2002)
