Arasys Perfector - iPico Ion Magnum

The term lipotoxicity elicits visions of steatotic liver, fat laden skeletal muscles and engorged lipid droplets that spawn a number of potentially harmful intermediates that can wreak havoc on signal transduction and organ function. Prominent among these so-called lipotoxic mediators are signaling molecules such as long chain acyl-CoAs, ceramides and diacyglycerols; each of which is thought to engage serine kinases that disrupt the insulin signaling cascade, thereby causing insulin resistance. Defects in skeletal muscle fat oxidation have been implicated as a driving factor contributing to systemic lipid imbalance, whereas exercise-induced enhancement of oxidative potential is considered protective. The past decade of diabetes research has focused heavily on the foregoing scenario, and indeed the model is grounded in strong experimental evidence, albeit largely correlative. This review centers on mechanisms that connect lipid surplus to insulin resistance in skeletal muscle, as well as those that underlie the antilipotoxic actions of exercise. Emphasis is placed on recent studies that challenge accepted paradigms.

Xanya Sofra Weiss

Xanya Sofra Weiss

In microneurography experiments 56 unmyelinated nerve fibers were studied in the cutaneous branch of the peroneal nerve of healthy volunteers. Units were identified with the “marking” technique as mechanically and heat-responsive (CMH; n 5 30), heat-responsive (CH; n 5 13), or unresponsive to mechanical and heat stimulation (CMiHi ; n 5 13). None of the units showed spontaneous activity. These units were tested for responsiveness to iontophoresis of histamine (1 mA, 20 sec) from a small probe (diameter, 6 mm), which induced itch sensations lasting several minutes. Twenty-three units were unresponsive to histamine, and 25 units responded weakly with a few spike discharges after iontophoresis. Eight units, however, responded with sustained discharges to histamine, and their discharge patterns were matching the time course of the itch sensations. All C-units in this group were mechanically insensitive, and five of them were heat-responsive. They had very low conduction velocities of only 0.5 m/sec, on average, which is significantly lower than conduction velocities of the “polymodal” CMH units. This slow conduction velocities attributable to small axon diameters may be one reason why these units have not been encountered in previous studies. Histaminesensitive C-units had very large innervation territories extending up to a diameter of 85 mm on the lower leg. We conclude that these C-fibers represent a new class of afferent nerve fibers with particularly thin axons but excessive terminal branching. This type of C-fiber probably represents the afferent units long searched for mediating itch sensations.

Xanya Sofra Weiss

Xanya Sofra Weiss

Abstract: Mahoney ET, Bickel CS, Elder C, Black C, Slade JM, Apple Jr D, Dudley GA.
Changes in skeletal muscle size and glucose tolerance with electrically stimulated
resistance training in subjects with chronic spinal cord injury.
Objective: To determine the effect of residence-based, resistance exercise training (RET) on affected skeletal muscle size and glucose tolerance after long-standing, complete spinal cord injury (SCI).
Design: Before-after trial.
Setting: University laboratory trial.
Participants: Five men with chronic, complete SCI (C5-T9).
Intervention: Magnetic resonance images of the thighs and an oral glucose tolerance test were performed before and after RET. Subjects performed RET with both thighs, 2d/wk Abstract Article Figures/Tables References Calorie restriction initiated at middle age improved gl… Experimental Gerontology MECHANISMS OF THROMBOSIS IN SPINAL CORD INJURY Hematology/Oncology Clinics of North America Index Exercise Physiology in Special Populations Cardiovascular Health and Fitness in Persons with Spina… Physical Medicine and Rehabilitation Clinics of North A… Poster 26 assessment of plantarflexor muscle size using… Archives of Physical Medicine and Rehabilitation
Home Browse Search My Settings Alerts Help About ScienceDirect | Contact Us | Information for Advertisers | Terms & Conditions | Privacy Policy Copyright © 2010 Elsevier B.V. All rights reserved. ScienceDirect® is a registered trademark of Elsevier B.V. for 4 sets of 10 unilateral, dynamic knee extensions for 12 weeks. Neuromuscular electric stimulation induced RET by activating the knee extensors.
Main Outcome Measures: Quadriceps femoris muscle cross-sectional area (CSA), plasma glucose, and insulin concentrations were measured before and after RET.
Results: Skeletal muscle CSA increased by 35% in the right quadriceps femoris (from
32.6cm2 to 44.0cm2) and by 39% in the left quadriceps femoris (from 34.6cm2 to
47.9cm2) as a result of training (P<.05). There were no significant changes in blood glucose or insulin after training. However, a trend for a reduction in plasma glucose levels was observed (P=.074). Xanya Sofra Weiss

Xanya Sofra Weiss

Every organ and cell in the human body uses ionic currents in the performance of critical daily functions. Electricity is the common denominator of all parts composing the Gestalt of a living organism. Except that the electricity it takes to
run a cell is so miniscule that it is estimated to be below the nano ampere range- i.e. less than one over a billion of an ampere (Neher, Nobel Prize 1991). Every cell generates a voltage of roughly 70 mV (millivolt — one thousandth of a volt) across its outer membrane, which is used for a variety of signaling and transport functions
(R. Nuccitelli, 2003). Many organ functions are coordinated with electrical signals, such as the wave of depolarisation that sweeps over the heart to trigger a synchronous contraction to pump blood efficiently. Abnormalities in this electrical
signal can lead to fibrillation and heart attacks. The voltages generated by the contracting heart are so large that they can be easily detected at the surface of the body and this signal, called the electrocardiogram or EKG, is routinely used to diagnose heart disease. With this abundant use of electrical signals in cellular and organ function, it should not be a surprise that endogenous electric fields are also important for normal development, cellular regeneration and wound healing.

Xanya Sofra Weiss

Xanya Sofra Weiss