UNBC Musculoskeletal System PDF

Summary

This document provides a detailed overview of the structure and function of the musculoskeletal system, covering bones, joints, and muscles. It includes diagrams, tables, and descriptions of various aspects of the system.

Full Transcript

Structure and Function of the
MusculoSkeletal System
Nursing 302
Structure and Function of Bones
Gives form to the body
Supports tissues
Permits movement by providing points of attachment for muscles
Protects many vital organs
Serves as a site for blood cell formation
Plays a role in mineral and hormone homeostasis
Elements of Bone Tissue
Rigid connective tissue
Constituents
Cells
Fibres
Ground substance
Crystallized minerals
Elements of Bone Tissue (Cont.)
Bone cells enable bone to grow, repair, change shape, synthesize new
bone tissue, and resorb old tissue
Bone matrix
Calcification
Bone Cells
Osteoblasts
Derived from mesenchymal stem cells
Primary bone-producing cells
Respond to parathyroid hormone
Produce osteocalcin
Synthesize osteoid
Nonmineralized bone matrix
Express the cytokine receptor activator nuclear factor kappa-B ligand (RANKL)
Necessary for forming osteoclasts
Bone Tissue
Osteocytes
Transformed osteoblasts that are surrounded in osteoid as it hardens from
deposited minerals
Synthesize matrix molecules
Key regulators of both bone formation and resorption
Osteoclasts
Major reabsorptive cells of the bone
Large, multinucleated cells
Bone Cells

A and C, from Damjanov, I., & Linder, J. (Eds.). (1996). Anderson’s pathology (10th ed.). St
Louis, MO: Mosby; B, from Wikimedia Commons, courtesy Robert M. Hunt.

A, Magnified view of compact bone. B, Longitudinal section of a
long bone showing both cancellous and compact bone. C, Section of a flat bone
OPG/RANKL/RANK System
Osteoprotegerin (OPG)
Glycoprotein that inhibits bone remodelling/resorption, inhibiting osteoclast
formation
Key in the interaction between osteoblasts and osteoclasts
RANKL is an essential cytokine needed for the formation and
activation of osteoclasts
When RANKL binds to its receptor RANK on osteoclast precursor cells, it
triggers their proliferation and increases bone resorption
Bone Matrix
Collagen fibres
Make up bulk of bone matrix
Proteoglycans
Strengthen bone
Play role in bone calcium deposition and calcification
Bone Matrix (Cont.)
Glycoproteins
Control collagen interactions that lead to fibril formation
Sialoprotein, osteocalcin, bone albumin, α-glycoprotein
Bone minerals
Two phases of mineralization
Formation of the initial mineral deposit
Proliferation or accretion of additional mineral crystals on the initial mineral deposits
Calcium and phosphate
Bone Tissue
Compact (cortical) bone
85% of the skeleton
Highly organized, solid, and extremely strong
Haversian system
Haversian canal, lamellae, lacunae, osteocyte, and canaliculi
Spongy (cancellous) bone
Lack haversian systems
Trabeculae
Periosteum
From Patton, K.T., & Thibodeau, G.A. (2016). Anatomy & physiology
(9th ed.). St Louis, MO: Mosby. Photo courtesy Dennis Strete.
Characteristics of Bone
206 bones in human skeleton
Axial skeleton
80 bones
Skull
Vertebral column
Thorax
Appendicular skeleton
126 bones
Upper and lower extremities
Shoulder girdle
Pelvic girdle
 Skeleton

From Drake, R., Vogl, A.W., Mitchell, A.W.M., et al. (2015). Gray’s
atlas of anatomy (2nd ed.). Philadelphia, PA: Churchill Livingstone.
Bones
Long bones
Diaphysis
Metaphysis
Epiphysis
Epiphyseal plate
Medullary (marrow) cavity
Endosteum
Long Bone

From Solomon, E. (2016). Introduction to human
anatomy and physiology (4th ed.). St Louis, MO:
Saunders.
Bones
Flat bones
Ribs
Scapulae
Short bones (cuboidal bones)
Wrists
Ankles
Irregular bones
Vertebrae
Mandibles
Facial bones
1. Which is TRUE regarding the human skeleton?

A. There are 280 bones in the skeleton.
B. Axial skeleton consists of 126 bones.
C. Skeleton contributes to 50% of total body weight.
D. Axial skeleton consists of the skull, vertebral column, and thorax.
Maintenance of Bone Integrity
Remodelling
Basic multicellular units
Repair of microscopic bone injuries
Existing bone is resorbed and new bone is laid down to replace it
Three phases:
Activation of the remodelling cycle
Resorption
Formation of new bone
 Bone Remodelling

Adapted from Nucleus Medical Art. D, from Damjanov, I., & Linder, J. (Eds.). Anderson’s pathology (10th ed.). St Louis, MO: Mosby.
Bone Repair
New bone is the final result
Stages:
Inflammation/hematoma formation
Procallus formation
Callus formation
Callus replacement
Remodelling
Structure and Function of Joints
Joint
Also called articulation
Site where two or more bones meet/attach
Provides stability and mobility to the skeleton
Joints
Joint classifications based on movement
Synarthrosis
Immovable
Amphiarthrosis
Slightly movable
Diarthrosis
Freely movable
Joints (Cont.)
Joint classifications based on structure
Fibrous
Joins bone to bone
Suture, syndesmosis, gomphosis
Cartilaginous
Symphysis and synchondrosis
Synovial
Uniaxial, biaxial, or multiaxial
Joint capsule, synovial membrane, joint cavity, synovial fluid, articular cartilage
Joints (Cont.)
Joint (articular) capsule
Fibrous connective tissue that covers the ends of bones where they meet in a joint
Synovial membrane
Smooth, delicate inner lining of joint capsule found in the nonarticular portion of the synovial joint
and any ligaments or tendons that traverse this cavity
Vascular subintima
Thin cellular intima
Joint (synovial) cavity
Enclosed, fluid-filled space between articulating surfaces of two bones
Enables two bones to move “against” one another
Joints (Cont.)
Synovial fluid
Superfiltrated plasma from blood vessels
Lubricates joint surfaces
Nourishes the pad of the articular cartilage
Covers the ends of the bones
Articular cartilage
Layer of hyaline cartilage that covers the end of each bone
Reduces friction in the joint
Distributes the forces of weight bearing
Composed of chondrocytes and intracellular matrix. From Dorland. (2012). Dorland’s medical illustrated dictionary (32nd ed.). St Louis, MO: Saunders.
Skeletal Muscles
Millions of individual muscle fibres that contract and relax to facilitate movement
75% water, 20% protein, 5% organic and inorganic compounds
More than 600 in body
2 to 60 cm long
Fusiform muscles
Elongated muscles shaped like straps
Pennate muscles
Broad, flat, and slightly fan-shaped
Skeletal Muscles (Cont.)
Epimysium
Outermost layer
Tendon
Perimysium
Fascicles
Endomysium
Smallest unit of muscle visible without a microscope
Muscle
Skeletal muscle
Voluntary
Striated
Extrafusal
Motor unit
Functional unit of the neuromuscular system
Composed of lower motor neurons
Sensory receptors
Spindles
Golgi tendon organs
Motor Units
Muscle Fibres
Each muscle fibre is a single muscle cell
Myofibrils
Fibre’s functional subunits
Myoblasts
Precursor cells
Main cells responsible for muscle growth and regeneration
Satellite cells
Myoblasts in dormant state
Muscle Fibres (Cont.)
White muscle (type II fibres)
Fast twitch
Red muscle (type I fibres)
Slow twitch
Muscle membrane
Sarcolemma and basement membrane
Sarcoplasm
Cytoplasm of the muscle cell
Contains enzymes and proteins responsible for the cell’s energy production, protein
synthesis, and oxygen storage
Muscle Fibres (Cont.)
Sarcotubular system
Transverse tubules
Sarcoplasmic reticulum
Sarcotubules
Sarcomere
Muscle Fibres (Cont.)
Myofibrils
Functional units of muscle contraction
Contains sarcomeres
Speed with which sarcomeres lengthen and shorten during movement directly
influences the strength and function of skeletal muscles
Most abundant subcellular muscle component
Composed of myofilaments
Muscle Structure

From Solomon, E. (2016). Introduction to human anatomy and physiology (4th ed.). St Louis, MO: Saunders.
Muscle
Nonprotein constituents of muscle
Nitrogen, creatine, creatinine, phosphocreatine, purines, uric acid, and amino
acids all serve in the complex process of muscle metabolism
Energy is provided by glycogen
Creatinine is formed in muscle from creatine
Inorganic compounds, anions, and cations are important in the regulation of
protein synthesis, muscle contraction, and enzyme systems, as well as in the
stabilization of cell membranes
Muscle Contraction
Excitation
Muscle fibre action potential
Coupling
Contraction
Cross-bridge theory
Relaxation
Muscle Metabolism
Requires constant supply of ATP and phosphocreatine
During activity, the need for ATP increases 100-fold
Stored glycogen and blood glucose are converted anaerobically to sustain
brief activity without increasing the demand for oxygen
Strenuous activity requires oxygen
Type I fibres can resist fatigue longer than type II fibres
Muscle Mechanics
All or nothing response
Repetitive discharge
Allows the muscle to activate the number of motor units needed to generate
the desired force
Physiological tetanus
Occurs when motor units are stimulated again and the muscle unit has not
been able to relax between stimulation and the next contraction
Muscle Contractions
and Movement
Types of muscle contractions
Isometric
Dynamic
Eccentric
Concentric
Muscle movement
Agonist
Antagonist
Dynamic and Isometric Contraction

From Patton, K.T., & Thibodeau, G.A. (2016). Structure & function of the body (15th ed.). St Louis, MO: Mosby..
Tendons and Ligaments

Tendons Ligaments
Attach muscle to bone Attach bone to bone
Transfer forces from muscle to Stabilize joints against excessive
bone movement
Act as a type of biological spring
for muscles to allow additional
stability during movement
Aging and the
Musculo-Skeletal System
Bones
Bone loss
Less dense, less strong, more brittle
Bone remodel time is lengthened
Joints
Cartilage becomes more rigid, fragile, susceptible to fraying
Decreased range of motion
Aging and the Musculo-
Skeletal System (Cont.)
Muscles
Sarcopenia
Decrease in muscle mass and strength
Reduced oxygen intake, basal metabolic rate, and lean body mass