Ch. 1 - Structure and Function of Body Systems 2024 PDF

Summary

This document provides an overview of the structure and function of body systems, focusing on kinesiology and the musculoskeletal system. It discusses various aspects of muscles, including fiber types, contraction mechanisms, and neuromuscular activation. The document includes information on different types of muscle fibers and how muscles work together.

Full Transcript

KINESIOLOGY

Structure and Function of Body Systems
KINESIOLOGY

Structure and Function of Body Systems
KINESIOLOGY Objectives

1. Identify macrostructure and microstructure of muscle and connective tissue.

2. Describe the sliding-filament theory of muscle contraction.

3. Describe physiological characteristics of muscle fiber types.

4. Identify structures of cardiovascular and respiratory systems and their
function during exercise.
KINESIOLOGY
KINESIOLOGY Musculoskeletal System

Bones, muscles, and connective tissue

Muscles pull on bones to create pushing or
pulling forces against external objects
KINESIOLOGY
KINESIOLOGY Skeletal System

Joints – junction of bones

Joints can be classified by:
– Degree of movement
Fibrous joint – no movement
Cartilaginous joint – allows limited movement
Synovial joint – allows greatest movement

– Number of directions in which rotation can occur
KINESIOLOGY Skeletal System

Synovial joints:
– Hyaline cartilage
– Synovial capsule with fluid
– Supporting connective tissue (i.e. ligaments)

Types of synovial joints:
– Non-axial
– Uniaxial
– Biaxial
– Multiaxial
KINESIOLOGY Skeletal Muscle

What is the largest organ system in the body?
KINESIOLOGY Skeletal Muscle
KINESIOLOGY Skeletal Muscle

Muscle fiber – muscle cell

Muscle fascicles – bundles of muscle fibers

Muscles – an organ that contains contractile proteins,
connective tissue, nerves, and blood vessels.
KINESIOLOGY
KINESIOLOGY Skeletal Muscle

Epimysium – outer fibrous covering of the muscle

Perimysium – covers muscle fascicles

Endomysium – covers muscle fibers

Contiguous with the muscle tendon
– Attaches to bone periosteum
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How does foam rolling work?
KINESIOLOGY
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Institute ofofHuman
Anatomy Myofascial
Anatomy
Release

Institute of Human Anatomy
Anatomy of Myofascial Release
KINESIOLOGY Skeletal Muscle

Sarcolemma – outer membrane
– Contiguous with endomysium

Sarcoplasm – fluid portion
(cytoplasm) of the muscle fiber
– contains proteins, glycogen, lipids,
enzymes, and other organelles
KINESIOLOGY Skeletal Muscle

Myofibrils – groups of contractile
proteins

Mitochondria – metabolic center of
the muscle fiber
KINESIOLOGY Skeletal Muscle

Sarcoplasmic reticulum:
– tubule system running parallel to
myofibrils
– Storage cite of calcium

Transverse tubules (T-tubules):
– tube system that extends from the
sarcolemma to sarcoplasmic reticulum
– Important for transmitting electrical
impulses
KINESIOLOGY Skeletal Muscle

Nucleus – organelle that contains gene information
– Skeletal muscle is multi-nucleic

Satellite cells – cells that can donate a nuclei to the
muscle fiber
– Important for muscle growth and repair
KINESIOLOGY
KINESIOLOGY Skeletal Muscle

Sarcomere – smallest contractile unit of skeletal muscle
– Repeated longitudinally throughout the muscle fiber
– Made up of protein myofilaments

Myosin – protein containing a globular head and polypeptide
tails
– Thick filament

Actin – two polypeptide protein strands arranged in a double
helix
– Thin filaments
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Six actin filaments surround one myosin filament, while each
actin filament is surrounded by three myosin filaments.
KINESIOLOGY Skeletal Muscle

Tropomyosin – tube-shaped protein twisted around the actin
filament and lies in the groove between the double-helix
– Responsible for inhibiting the actin and myosin coupling

Troponin – protein embedded at regular intervals along actin
and tropomyosin
– High affinity for calcium ions (Ca2+)
– Regulates tropomyosin
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Z-line: anchors actin filaments
– Sarcomere extends from z-line to z-line

I-band: region where only actin is located
– Light portion

H-zone: region where only myosin is located
– Dark portion

A-band: region where myosin and actin overlap
– Dark portion
KINESIOLOGY
KINESIOLOGY Muscle Contraction

Motor unit
– a motor neuron and the muscle fibers
that it innervates
– One motor neuron may innervate a few
fibers up to thousands
KINESIOLOGY Muscle Contraction

Neuromuscular junction – location where motor neuron
and muscle fiber innervate
– Motor end plate – sarcolemma pocket formed
around motor neuron
– Synaptic cleft – gap between neuron and
muscle fiber
– Acetylcholine – neurotransmitter released
from motor neuron to stimulate muscle fiber
KINESIOLOGY Muscle Contraction

Video Explanation
KINESIOLOGY Muscle Contraction

Actin filaments slide inward over myosin filaments

Z-lines pulled together, shortening the sarcomere

Relaxed Contracting Fully Contracted
KINESIOLOGY Muscle Contraction

The number of crossbridges between actin and myosin
dictates the force production of the muscle.
Length-Tension Relationship
KINESIOLOGY
KINESIOLOGY Muscle Contraction

Step 1: Action potential from alpha motor neuron
Step 2: Release of acetylcholine into the NMJ
– ACh binds to receptors
Step 3: Depolarization across sarcolemma
– Action potential travels down T-tubules
Step 4: Ca2+ released from sarcoplasmic reticulum
Step 5: Ca2+ binds to troponin
– Troponin causes shift in tropomyosin
– Myosin biding sites uncovered
KINESIOLOGY Muscle Contraction

Step 6: Myosin binds to actin to form crossbridge
Step 7: ATP split and energy produces power stroke
Step 8: New ATP binds to myosin
– Crossbridge released
Step 9: Steps 6-8 continue if:
– Sufficient Ca2+ and ATP
Step 10: Motor neuron stimulation ceases
– Calcium pumped back into sarcoplasmic reticulum
– Muscle relaxes; sarcomere returns to resting state
KINESIOLOGY Muscle Contraction

Resting Phase
– Low calcium binding → minimal crossbridge formation

Excitation-Contraction Coupling Phase
– Action potential → increased calcium release → crossbridge formation

Contraction Phase
– ATP hydrolysis → power stroke → sarcomere shortens

Relaxation Phase
– Decreased motor neuron activation → calcium pumped back into SR →
myosin detachment → sarcomere returns to resting state
KINESIOLOGY Muscle Contraction

Sliding Filament Video 1
Sliding Filament Video 2
KINESIOLOGY Neuromuscular Activation

Muscle control depends on number of fibers in motor
unit
– Muscles with fine motor skills may have as few as one fiber
per unit
– Muscles with less precision may have several hundred fibers

All or none principle
– All muscle fibers in a motor unit will contract when stimulated
KINESIOLOGY Neuromuscular Activation

Each action potential produces a brief
contraction:
– a twitch
– Calcium is released and removed quickly

If second twitch is elicited before muscle
relaxes, the two twitches summate
– Force is greater than single twitch

If twitch frequency becomes high enough, the
twitches fuse a = single twitch
– Tetanus b = summation of two twitches
– Individual twitches blend into sustained
contraction c = unfused tetanus

d = fused tetanus
KINESIOLOGY
KINESIOLOGY Muscle Fiber Types

Muscles contain fibers of different morphological and
physiological characteristics

Common classification is based on twitch time
– Slow-twitch: develops force and relaxes slowly
long twitch time
– Fast-twitch: rapid force production and relaxation
short twitch time
KINESIOLOGY Muscle Fiber Types

Biochemical classification
– Classified by ability to supply and utilize energy for contraction

Aerobic capacity
– Number of capillaries
– Number of mitochondria
– Amount of myoglobin
– Enzyme content
– Fiber size (amount of contractile proteins)
KINESIOLOGY Muscle Fiber Types

Mechanical classification
– Force production capacity
– Speed of contraction and relaxation
– Power output (force × velocity)
– Fatigue resistance
KINESIOLOGY Muscle Fiber Types

Type I fibers
– Slow-twitch
– Aerobic fibers

Type IIa
– Fast-twitch
– Aerobic-anaerobic fibers

Type IIx Light Blue = Type I fibers
– Fast-twitch Green = Type IIa fibers
Dark Blue = Type IIx fibers
– Anaerobic fibers
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KINESIOLOGY Muscle Fiber Types
Endurance Strength/Power
70% Slow; 30% Fast 70% Fast; 30% Slow

Inter-individual variability
Differences between muscles

Adapted from S&Cresearch.com
KINESIOLOGY
KINESIOLOGY Motor Unit Recruitment

Force production can be varied through:
– Frequency of activation (rate coding)
– Number of motor units activated
Size principle
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Comparison of paused vs. touch and go reps during bench press

*
Mean Velocity (m∙s-1)

*

*

*

% of 1RM

* significantly different from TNG reps (p < 0.05).
Osborn and Gwaltney, in prep
KINESIOLOGY

Can an athlete vertical jump higher with a
countermovement or in a static squat position?
KINESIOLOGY Proprioception

Muscle spindles
– Aka intrafusual fibers
– Detect rate and changes in muscle length
– Feedback sent to spinal cord (afferent)
– Alpha motor neuron stimulation (efferent)
– Aids in activities such plyometrics

Stretch-shortening cycle (SSC)
– Stretch-reflex (muscle spindles)
– Series elastic component
KINESIOLOGY Proprioception

Golgi Tendon Organ (GTO)
– Located in musculotendinous junction
– Senses tension
– Activation → muscle inhibition
– Desensitized through training
KINESIOLOGY Cardiovascular System

CV system:
– Heart (pump)
– Circulatory system (vessels)
– Blood (fluid)

Functions:
– Delivery of nutrients
– Removal of metabolic byproducts
– Transport of hormones
– Temperature regulation
KINESIOLOGY Cardiovascular System

Chambers
– atria
– ventricles

Valves
– Atrioventricular valves:
tricuspid – right
mitral – left
– Semilunar valves
pulmonary – right
aortic - left
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Sinoatrial (SA) node
– intrinsic control (approx. 60-80 bpm)
– location where electrical impulses are initiated

Atrioventricular (AV) node
– Location where impulse is delayed before passing to ventricles

Atrioventricular (AV) bundle
– Transmits impulses to the ventricles

Left and right bundle branches
– Branches of the AV bundle transmitting the impulse to the ventricles
– Contains Purkinje fibers which transmits impulses throughout the ventricles
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KINESIOLOGY Autonomic Control

Cardiovascular control center in medulla transmits signals via:
– Sympathetic nervous system
– Parasympathetic nervous system

Sympathetic nervous system
– Cardiac accelerator nerves
– Increases heart rate by stimulating the SA node (chronotropic effect)
– Increase heart rate > 200 bpm

Parasympathetic nervous system
– Vagus nerve
– Decreases heart rate by inhibiting the SA and AV node (vagal tone)
– Decrease heart rate as low as 30 bpm
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P-wave
– Atrial depolarization

QRS complex
– Ventricular depolarization
– Atrial repolarization

T-wave
– Ventricular repolarization
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KINESIOLOGY Cardiovascular System

Close-circuit system
– Arterial system – carries blood from the heart
Arteries and arterioles
Strong, muscular walls; high pressure
– Venous system – carries blood to the heart
Veins and venules
Low pressure
Skeletal muscle pump; One-way valves
– Capillaries
Exchange of O2, CO2, nutrients, fluids, etc.
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Skeletal Muscle Pump
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Blood
– Plasma
Liquid portion
Contains proteins, hormones, etc.
– Cells
Red blood cells
– Contains hemoglobin
White blood cells
– Immune function
Platelets
– Blood clotting
KINESIOLOGY Respiratory System

Nose and nasal cavity
– Purifies, humidifies, and warms air

Transport into lungs
Pharynx → larynx (vocal) → trachea →
bronchi → bronchioles

Alveoli
– Location of gas exchange in the lungs
KINESIOLOGY
KINESIOLOGY Respiratory System

Lungs recoil and expand
– Diaphragm and muscles around the rib cage

Inspiration
Diaphragm contracts (depresses and flattens)
Vacuum to pull air into the lungs

Expiration
Diaphragm relaxes (elevates)
Elastic recoil forces air out of the lungs

Rest vs. Exercise
– Diaphragm controls air exchange during rest
– Heavy exercise requires muscles around the rib cage to assist
Inspiration: external intercostals, SCM, anterior serratus, and scalenes
Expiration: rectus abdominus, obliques, transverse abdominus, internal intercostals
KINESIOLOGY Respiratory System

Pleural pressure
– Pressure in the narrow space between the lung pleura and
chest wall pleura
– Pleura – membrane enveloping the lungs and lining the chest
wall
– Expansion of rib cage:
Pressure decreases
Increases air flow into lungs
– Depression of rib cage
Pressure increases
Forces air out of lungs
KINESIOLOGY Respiratory System

Alveolar pressure
– Pressure in the alveoli

Inspiration
– Alveolar pressure decreases below atmospheric pressure

Expiration
– Alveolar pressure increases above atmospheric pressure
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KINESIOLOGY Respiratory System

Diffusion
– Movement of molecules in opposite directions through the
alveolar capillary membrane
KINESIOLOGY Respiratory System

High concentration to low concentration
– partial pressure of O2 is approx. 60 mmHg higher than
pulmonary capillaries at rest
O2 easily diffuses into capillaries to be transported
– Partial pressure of CO2 is lower than pulmonary capillaries
CO2 diffuses into aveoli to be exhaled
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Next: Biomechanics of Resistance Exercise