“
“Purpose: To quantify the accumulation, progression, and distribution of fat separately in and around the supraspinatus muscle from
the onset of tendon detachment and to validate computed tomography (CT) for quantification of fat content by using volumetry and histomorphometry as reference standards.
Materials and Methods: Institutional animal care committee approval was obtained. The supraspinatus tendon of 30 adult female rabbits (3.0 kg) was detached. Rabbits were sacrificed in groups of 10 after 4, 8, and 12 weeks. Fifteen rabbits that did not undergo surgery served as control subjects. Fat accumulations in and around the proximal, middle, and distal supraspinatus muscle were quantified, volumetrically and histologically, and were compared with extramuscular presence and intramuscular attenuation at CT. Weight, volume, histologic findings, and CT
determinations of fat were compared Baf-A1 mouse by using one-way PARP inhibition analysis of variance. The Pearson test was used to correlate intramuscular fat accumulation with CT observations.
Results: Four weeks after tendon detachment significant extraand intramuscular fat had accumulated (both P < .05) and progressed during 12 weeks, with accumulation of extramuscular fat being three times greater than that of intramuscular fat (both P < .05). An increasing proximal-to-distal gradient existed for both extra- and intramuscular accumulation (both P < .05). CT depicted the onset, progression, and gradient of extra-
and intramuscular fat accumulation (all P < .05). CT attenuation correlated strongly with histologic findings (P < .05).
Conclusion: Fat accumulated early, along an increasing proximal-to-distal buy LEE011 gradient, and progressed with time after supraspinatus tendon detachment. CT proved to be a valid tool for monitoring the onset, progression, and gradient separately for extra- and intramuscular fat accumulation. (C) RSNA, 2010″
“The spatial structure of a microwave plasma torch driven by an azimuthally symmetric surface wave operating in a N-2-Ar mixture at atmospheric pressure is investigated. A two-dimensional (2D) self-consistent theoretical model is developed to investigate the entire spatial structure of the source, including the discharge zone, sustained by the field of the surface TM00 mode, and the postdischarge plasma. Maxwell’s equations, the rate balance equations for the most important excited species-vibrationally and electronically excited states, ions and nitrogen atoms N(S-4)-and the Boltzmann equation for electrons are consistently solved. Model calculations of the 2D spatial distributions of species of interest such as charged particles (electrons and positive ions), N-2(X 1 Sigma(+)(g), u) vibrationally excited molecules, N-2(A (3)Sigma(+)(u)) metastable molecules, and N(S-4) ground state atoms are presented and discussed. (C) 2011 American Institute of Physics. [doi:10.1063/1.