A laser Doppler instrument for in vivo measurements of blood flow in single renal arterioles.

A laser Doppler instrument has been developed to measure the blood flow in single vessels for the study of the dynamics of local control mechanisms. A commercial blood perfusion monitor, designed to measure blood perfusion in a vascular field containing many randomly oriented blood vessels, was modified to perform measurements of blood flow in a single arteriole. In vitro tests of the instrument revealed that the relationship between blood flow and Doppler shift was not a simple linear function. Causes of nonlinearity are revealed and proper use of the device avoids the problem. The device was applied to efferent arterioles that are visible on the surface of the rat kidney. An angiotensin converting enzyme inhibitor and graded doses of angiotensin II were used to perturb kidney blood flow. The induced changes in whole kidney blood flow, measured with an electromagnetic flow probe, and in single efferent arteriolar blood flow, measured with the new instrument, were correlated. An oscillation at approximately 0.035 Hz, previously described in the tubular pressure and attributed to a local feedback mechanism acting on arteriolar resistance, was found in the arteriolar blood flow. The new instrument is easy to use and provides temporal resolution not available with more conventional methods used for flow measurement in the microcirculation.

Coherent range-gated laser displacement metrology with compact optical head.

We describe a new architecture for laser displacement metrology with a drastic reduction in the size and complexity of the optical head. Connected by a single optical fiber, the compact heads are easy to integrate and readily multiplexed to support applications requiring large numbers of sensors. The approach is made possible by modulating the outgoing laser light with a binary random noise code, allowing the detected signals to be discriminated based on their propagation delay. We demonstrate a displacement resolution of 1.1 nm rms.

MSTAR: a submicrometer absolute metrology system.

The Modulation Sideband Technology for Absolute Ranging (MSTAR) sensor permits absolute distance measurement with subnanometer accuracy, an improvement of 4 orders of magnitude over current techniques. The system uses fast phase modulators to resolve the integer cycle ambiguity of standard interferometers. The concept is described and demonstrated over target distances up to 1 m. The design can be extended to kilometer-scale separations.