Exercise Science & Sport Studies

Slides:

Advertisements

Similar presentations

Skeletal Muscle Activity: Contraction

Advertisements

A Slides 1 to 110 Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings.

Muscle Physiology Chapter 11. Connective Tissue Components Muscle cell = muscle fiber Endomysium – covers muscle fiber Perimysium – binds groups of muscle.

Muscle Specialized for: Types:.

Muscle Physiology Chapter 1.

Muscle Function.

Chapter 6: Muscular System

Physiology of Muscles The Sliding Filament Theory

Structure and Function of Exercising Muscle

Muscle Tissue and Organization

Chapter 11 Muscular Tissue ehow.com.

Chapter 1 Structure and Function of Exercising Muscle.

Fig 12.1 P. 327 Each somatic neuron together with all the muscle fibers it innervates. Each muscle fiber receives a single axon terminal from a somatic.

Chapter 1 MUSCLES AND HOW THEY MOVE.

Muscular system SKELETAL MUSCLE Skeletal muscle is made up of hundreds of muscle fibers –Fibers consists of threadlike myofibrils –Myofibrils composed.

Function depends on structure

Chapter 12a Muscles.

Physiology of Skeletal Muscle Contraction. The Muscle Action Potential ( AP ) The Muscle Action Potential ( AP ) Muscle RMP = -90 mV ( same as in nerves.

Anatomy and Physiology

Muscular System Chp. 6.

Muscular Control of Movement. Review of Anatomy Types of Muscles –Smooth: blood vessels and organs –Cardiac: heart –Skeletal: muscles for movement.

Types of Muscles Smooth  Involuntary muscle; controlled unconsciously  In the walls of blood vessels and internal organs Cardiac  Controls itself with.

Muscle Structure and Function

The Muscular System What do skeletal muscles do? How do muscles work?

Skeletal Muscle Key words:. Overview of the Muscle Fiber Structure Muscle fibers (cells) are composed of myofibrils Myofibrils are composed of myofilaments.

Muscle Contraction Tendon – cord of dense fibrous tissue attaching the muscle to a bone. Epimysium – the sheath of fibrous connective tissues surrounding.

Diagram of a Neuron Terms to Know: Dendrite Cell body Nucleus Axon Schwann Cell Myelin Sheath Node of Ranvier dendrite Myelin sheath axon Cell body Nodes.

Muscle Cells & Muscle Fiber Contractions

Muscle Physiology Chapter 7.

MUSCLES AND HOW THEY MOVE.

Cardiac Muscle Involuntary –heart only Contracts & relaxes continuously throughout life –Contracts without nervous stimulation! –A piece of cardiac muscle.

BTEC NC Sport & Exercise Sciences

Lecture # 17: Muscular Tissue

1 Structure of Skeletal Muscle We will begin our look at the structure of muscle starting with the largest structures and working our way down to the smallest.

EDU2EXP Exercise & Performance 1 The Exercising Muscle Structure, function and control.

Muscle Tissue A primary tissue type, divided into: A primary tissue type, divided into: –skeletal muscle –cardiac muscle –smooth muscle.

Co 7. Table 7.2 TABLE 7.2 Comparison of Muscle Types Smooth Muscle Skeletal Muscle Cardiac Muscle Location Appearance Cell Shape Nucleus Special Features.

Structure of a Single Muscle Fiber. Skeletal Muscle Fiber Structure Key Points An individual muscle cell is called a muscle fiber A muscle fiber is enclosed.

1.What is a hypothesis? Create your own example. 2.How does a conclusion and hypothesis relate?

Exercise 14 Microscopic Anatomy, Organization, and

Muscular System. Muscle Video Characteristics of Muscles Skeletal and smooth muscle cells are elongated (muscle cell = muscle fiber) Contraction of muscles.

Ch : Contraction and Metabolism of Skeletal Muscle

The Muscular System Slide 6.1 Copyright © 2003 Pearson Education, Inc. publishing as Benjamin Cummings  Muscles are responsible for all types of body.

Sliding Filament.

Filaments Resting state Electrical impulse (Action Potential) reaches axon terminal.

Synapse – The site of connection between a neuron and a cell. Neurotransmitter – A chemical released at the neuron’s synapse that communicates with the.

MUSCLES I. GENERAL INFORMATION HOW MUSCLES ARE NAMED LOCATION Ex: TEMPORALIS NUMBER OF ORIGINS Ex: BICEPS BRACHII & TRICEPS BRACHII SIZE Ex: GLUTEUS.

Muscle Physiology Dynamics of Muscle Contraction MMHS Anatomy.

The Sliding Filament Theory

Neuromuscular Junction and Major Events of Muscle Contraction Quiz Review.

Muscular System The 3 Types of Muscles SKELETAL MUSCLE STRUCTURE.

Structure and Function of Exercising Muscle

MUSCLES I. GENERAL INFORMATION HOW MUSCLES ARE NAMED LOCATION Ex: TEMPORALIS NUMBER OF ORIGINS Ex: BICEPS BRACHII & TRICEPS BRACHII SIZE Ex: GLUTEUS.

The Muscular System. The characteristics of muscle tissue enable it to perform some important functions, including:  Movement – both voluntary & involuntary.

Muscular System Physiology. 1. Skeletal muscle tissue:  Attached to bones and skin  Striated  Voluntary (i.e., conscious control)  Powerful  Primary.

Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings WHOLE MUSCLE CONTRACTION:PART 1 Motor units All the muscle fibers innervated.

The Muscular System What do skeletal muscles do? How do muscles work?

Muscle Contractions. Muscles pull on tendon fibers Pull=Tension Tension is an active force Energy must be applied to produce an active force Applied tension.

MUSCULAR SYSTEM Part 3: Muscle Structure & Contraction.

Structure and Function of Skeletal Muscle. Skeletal Muscle Human body contains over 400 skeletal muscles 40-50% of total body weight Functions of skeletal.

Muscle Physiology PSK 4U1.

MUSCLES AND HOW THEY MOVE.

Muscle Physiology Chapter 11.

Musculoskeletal System - Muscles

NOTES: The Muscular System (Ch 8, part 2)

Muscle relationships and types of contractions

The Muscular System.

Chapter 9 Muscular System

Presentation transcript:

Exercise Science & Sport Studies Physiological Principles of Conditioning for Sports Dr. Moran EXS 558

Class Textbook Class Website Physiological Aspects of Sport Training and Performance J. Hoffman http://www.amazon.com/exec/obidos/ASIN/0736034242/interactiveda162-20/102-3304755-7467337 Class Website http://web.cortland.edu/moranm/EXS558/EXS558.html Download weekly readings (.PDF) Research source links EXS 558

Neuromuscular System Outline Muscle Types Skeletal Muscle Design a. Myofibrils (Actin and Myosin) Sliding Filament Theory Factors Influencing Muscle Force Production Excitation-Contraction Coupling Muscle Fiber Types a. Slow b. Fast (Oxidative-Glycolytic) c. Fast Glycolytic EXS 558

Types of Muscle Skeletal w Voluntary muscle; controlled consciously Over 600 throughout the body Cardiac w Controls itself with assistance from the nervous and endocrine systems w Only in the heart Smooth w Involuntary muscle; controlled unconsciously In the walls of blood vessels and internal organs EXS 558

Design of Skeletal Muscle Epimysium (connective tissue) surrounds whole muscle Fasicles (groups of fibers) surrounded by perimysium Myofibrils surrounded by endomysium Responsible for contraction Sarcolemma surrounds cellular contents of each muscle fiber EXS 558

Myofibrils Composed of myofilaments Consist mainly of two proteins MYOSIN (thick) Features globular heads acting as ATPase (determines rate of contraction) M-line in middle of myosin molecule, heads on each side move toward M-line (bipolar) ACTIN (thin): -two intertwined subunits (forms groove) -no ATPase (“molecular motor”) -terminated at Z-line EXS 558

Sarcomere: Z-line to Z-line M line: “naked” region – which way muscle pulls depends on which side is better anchored (ex: curl vs chin up) Level of Filament Overlap dictates Force Production EXS 558

Sliding Filament Theory (Huxley 1969) Wrapped around ACTIN is Tropomyosin Associated with tropomyosin is Troponin Troponin consists of three subunits: TnI – bound to actin TnT – bound to tropomyosin TnC – bound to calcium EXS 558

Sliding Filament Theory (con’t) When calcium is released from SR, it binds to TnC Causes conformational shift (transmitted to rest of troponin and to tropomyosin) Causes conformational shift in ACTIN ( exposes active sites) MYOSIN’s ATPase cleaves bound ATP (myosin-ADP-Pi) Myosin-ADP-Pi binds to active site (release of ADP-Pi) Actomyosin complex formed “Power stroke” occurs at myosin cross-bridge heads (shortening) Following flexion of cross-bridge, ATP binds to myosin Release myosin cross-bridge from ACTIN (relaxation) Process repeats or stops when intercellular calcium ↓ EXS 558

EXS 558

ACTIN and MYOSIN do not change length! Shortening occurs asynchronously to provide continuous muscle action EXS 558

Factors Affecting Force Development # of cross-bridge formations - based upon probability - faster the movement of ACTIN, ↓ probability of cross-bridge formation EXS 558

Factors Affecting Force Development 2. Overlap of ACTIN-MYOSIN EXS 558

Motor Unit * The more delicate the movement the less fiber per motor unit as opposed to gross movements Nerve fiber + muscle it innervates = motor unit EXS 558

Excitation/Contraction Coupling - Electrical impulse conducted down axon of motor neuron - Release of Ach (acetylcholine) at nerve terminal - ACh crosses cleft and binds with AChR at endplate - Opens sodium channels and depolarizes (excites) endplate: endplate potential (EPP) - EPP causes depolarization (action potential) of entire sarcolemma surface, including T-tubules At specialized regions of T-tubule system there is a close proximity between its membrane and SR (terminal cisternae) In this region T-tubular membrane has dihydropyridine (DHP) receptors, that act as voltage sensors, sense depolarization EXS 558

Excitation/Contraction Coupling (con’t) In same region, membrane of SR has ryanodine receptors (Ca2+ channels) Depolarization causes conformational change in ryanodine receptors which causes Ca2+ influx Cascade Effect: release of Ca2+ causes additional Ca2+ channels to open Results in sharp in cystolic Ca2+ which then binds to troponin to stimulate muscle contraction EXS 558

EXS 558

Overview Muscle Fiber Action (continued) w Muscle action is initiated by a nerve impulse. w The nerve releases ACh, which allows sodium to enter and depolarize the cell. If the cell is sufficiently depolarized, an action potential occurs which releases stored Ca2+ ions. w Ca2+ ions bind with troponin, which lifts the tropomyosin molecules off the active sites on the actin filament. These open sites allow the myosin heads to bind to them. (continued) EXS 558

Overview (continued) Muscle Fiber Action w Once myosin binds with actin, the myosin head tilts and pulls the actin filament so they slide across each other. w Muscle action ends when calcium is pumped out of the sarcoplasm to the sarcoplasmic reticulum for storage. w Energy for muscle action is provided when the myosin head binds to ATP. ATPase on the myosin head splits the ATP into a usable energy source. EXS 558

Slow-Twitch (Type I) Muscle Fibers w High aerobic (oxidative) capacity and fatigue resistance w Low anaerobic (glycolytic) capacity and motor unit strength w Slow contractile speed (110 ms to reach peak tension) and myosin ATPase w 10–180 fibers per motor neuron w Low sarcoplasmic reticulum development EXS 558

Fast-Twitch (Type IIa) Muscle Fibers w Moderate aerobic (oxidative) capacity and fatigue resistance w High anaerobic (glycolytic) capacity and motor unit strength w Fast contractile speed (50 ms to reach peak tension) and myosin ATPase w 300–800 fibers per motor neuron w High sarcoplasmic reticulum development EXS 558

Fast-Twitch (Type IIb) Muscle Fibers w Low aerobic (oxidative) capacity and fatigue resistance w High anaerobic (glycolytic) capacity and motor unit strength w Fast contractile speed (50 ms to reach peak tension) and myosin ATPase w 300–800 fibers per motor neuron w High sarcoplasmic reticulum development EXS 558

Muscle Biopsy w Hollow needle is inserted into muscle to take a sample. w Sample is mounted, frozen, thinly sliced, and examined under a microscope. w Allows study of muscle fibers and the effects of acute exercise and exercise training on fiber composition. EXS 558

“Eccentric exercise-induced morphological changes in the membrane systems involved in excitation-contraction coupling in rat skeletal muscle” Takehura H. et al. (2001) EXS 558