Twelve tips for developing and implementing curriculum in dedicated 'collaborative classrooms'.

Many health professional schools may be investing time and resources on dedicated educational spaces intended to promote collaborative learning. Alone, innovative physical space or technologies are not sufficient to ensure success in this. Lesson plans informed by collaborative praxis, individual motivation, faculty development, learner feedback, and team interactions also play a necessary and substantial role.

Increased CaVbeta1A expression with aging contributes to skeletal muscle weakness.

Ca2+ release from the sarcoplasmic reticulum (SR) into the cytosol is a crucial part of excitation-contraction (E-C) coupling. Excitation-contraction uncoupling, a deficit in Ca2+ release from the SR, is thought to be responsible for at least some of the loss in specific force observed in aging skeletal muscle. Excitation-contraction uncoupling may be caused by alterations in expression of the voltage-dependent calcium channel alpha1s (CaV1.

Role of Ca2+, membrane excitability, and Ca2+ stores in failing muscle contraction with aging.

Excitation-contraction (EC) coupling in a population of skeletal muscle fibers of aged mice becomes dependent on the presence of external Ca(2+) ions (Payne, A.M., Zheng, Z.

Loss of skeletal muscle strength by ablation of the sarcoplasmic reticulum protein JP45.

Skeletal muscle constitutes approximately 40% of the human body mass, and alterations in muscle mass and strength may result in physical disability. Therefore, the elucidation of the factors responsible for muscle force development is of paramount importance. Excitation-contraction coupling (ECC) is a process during which the skeletal muscle surface membrane is depolarized, causing a transient release of calcium from the sarcoplasmic reticulum that activates the contractile proteins.

Motor neuron targeting of IGF-1 attenuates age-related external Ca2+-dependent skeletal muscle contraction in senescent mice.

A population of fast muscle fibers from aging mice is dependent on external Ca(2+) to maintain tetanic force during repeated contractions. We hypothesized that age-related denervation in muscle fibers plays a role in initiating this contractile deficit, and that prevention of denervation by IGF-1 overexpression would prevent external Ca(2+)-dependent contraction in aging mice. IGF-1 overexpression in skeletal muscle prevents age-related denervation, and prevented external Ca(2+)-dependent contraction in this work.

Motor neurone targeting of IGF-1 prevents specific force decline in ageing mouse muscle.

IGF-1 is a potent growth factor for both motor neurones and skeletal muscle. Muscle IGF-1 is known to provide target-derived trophic effects on motor neurones. Therefore, IGF-1 overexpression in muscle is effective in delaying or preventing deleterious effects of ageing in both tissues.

External Ca(2+)-dependent excitation--contraction coupling in a population of ageing mouse skeletal muscle fibres.

In the present work, we investigate whether changes in excitation-contraction (EC) coupling mode occur in skeletal muscles from ageing mammals by examining the dependence of EC coupling on extracellular Ca(2+). Single intact muscle fibres from flexor digitorum brevis muscles from young (2-6 months) and old (23-30 months) mice were subjected to tetanic contractile protocols in the presence and absence of external Ca(2+). Contractile experiments in the absence of external Ca(2+) show that about half of muscle fibres from old mice are dependent upon external Ca(2+) for maintaining maximal tetanic force output, while young fibres are not.

Neurogenesis of excitation-contraction uncoupling in aging skeletal muscle.

Excitation-contraction (EC) uncoupling is a major cause of decreased muscle force generating capacity (specific force). However, the underlying mechanisms of EC uncoupling in muscle from aging mammals have not been characterized. We propose that impaired motor neuron function with aging leading to muscle denervation, a process probably initiated earlier than detected by in vitro morphologic techniques, results in EC uncoupling.

Life-long calorie restriction in Fischer 344 rats attenuates age-related loss in skeletal muscle-specific force and reduces extracellular space.

The decline in muscle function is associated with an age-related decrease in muscle mass and an age-related decline in strength. However, decreased strength is not solely due to decreased muscle mass. The age-related decline in muscle-specific force (force/muscle cross-sectional area), a measure of intrinsic muscle function, also contributes to age-related strength decline, and the mechanisms by which this occurs are only partially known.