Contraction of skeletal muscles

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Presentation transcript:

Contraction of skeletal muscles

Muscles are stimulated by nerves The place where where the nerve meets the muscle is called the Neuromuscular junction

Neuromuscular Junction Motor unit – is composed of Motor neuron – type of neuron that stimulates muscle tissue Muscle fibers – many fibers attach to one motor neuron Range from as far as 10 to as many as 2000!

Neuromuscular Junction A closer look at the junction The actual axon of the motor neuron doesn’t touch the sarcolemma of the muscle fiber. The gap is called the synaptic cleft Axon terminal – end of the axon gets close to the sarcolemma Motor end plate – sarcolemma closest to the axon Synaptic end bulb – portion of the axon that swells at the end Synaptic vesicles – tiny sacs within the synaptic end bulbs that contain chemicals called neurotransmitters

The Junction

Neuromuscular Junction Physiology When a nerve impulse reaches the synaptic end bulb Ca2+ triggers the release of Actylcholine (ACh), the neurotransmitter ACh binds with the ACh receptors on sarcolemma This produces a muscle action potential that results in a muscle contraction

Sliding – filament mechanism of contraction This deals with the interaction between the actin and myosin myofilaments For this mechanism to work, there needs to be adequate Ca+ and energy.

Sliding

Sliding Myosin Sarcomere Head – also called cross bridges, pulls on thin filaments This causes the thin filaments to slide towards the center of the sarcomere Sarcomere The sliding of the myofilaments brings the z disks closer together The myosin can pull the thin filament so far inward that they overlap

Contraction of the muscle Energy for contraction A high energy molecule called creatine phosphate is present in muscle. Used to make ATP quickly during prolonged exercise. ATP  ADP + P + energy When creatine phosphate is depleted, glucose is broken down through processes called glycolysis and cellular respiration and ATP is made.

Contraction of the muscle Stimulus Threshold stimulus – any stimulus that causes a contraction All of none principle – states that when ever a threshold is reached, the muscle fiber will contract to the fullest extent.

Contraction of the muscle Physiology When a muscle fiber is relaxed, there is a low concentration of Ca2+ in the sarcoplasm. It is held in the sarcoplasmic reticulum (SpR) When a muscle fiber is contracted the SpR releases Ca2+ in to the sarcoplasm and it binds with the troponin activating the filament sliding mechanism.

Contraction of the muscle Steps of Sliding filament sequence Myosin head becomes activated as it splits ATP into ADP + phosphate using ATPase. Ca2+ enters the sarcoplasm from the SpR, binding to troponin moving the tropomyosin. The activated myosin can attach to exposed actin filament The myosin swivels and pulls the actin filaments past the thick myosin filament this called the Power stroke of the contraction. As the myosin head swivel, the ADP is released.

Contraction of the muscle Steps of sliding filament sequence continued…. When the power stroke is complete, ATP binds to the myosin head and it detaches from actin. ATP splits and returns myosin head to original position. Myosin head is ready to combine further down on the filament.

Contraction of the muscle Relaxation (two major changes) ACh is broken down by acetylcholinease (AChE), this stops the muscle action potentials Ca2+ is rapidly removed from the sarcoplasm and returned to the SpR, this stops the myosin head attaching to the actin filament because of the return of tropomyosin. Rigor mortis – state of rigidity after death

Kinds of Contractions Myogram – measurement of a muscle contraction Latent – when Ca2+ is released Contraction – when muscle contracts Relaxation – when muscle is relaxing After a muscle fiber contracts, there is a short period of time that it loses its excitability.

Kinds of Contractions Twitch – brief contraction of all the muscle fibers in a motor unit Tetanus – two stimuli are applied but the second one is delayed until after the refractory period Isotonic – when muscle shortens and pull on another structure Isometric – minimal shortening of muscle tension is increased greatly