Muscle Contraction and Types of Muscle
Can produce force from all directions
Ability of cardiac muscle to contract in any direction
Fatigue resistance
Ability of muscle fibers to resist fatigue
Muscle performance
Ability of muscle to generate force and perform work
Low pH
Acidic environment due to increase in lactic acid during muscle fatigue
Sprinting
Activity that relies on anaerobic metabolism in muscle
Long endurance
Activity that relies on fat metabolism in muscle
Scattered thick filaments with many myosin heads
Arrangement of filaments in smooth muscle
Ordered myofibrils
Arrangement of myofibrils in cardiac muscle
Thin filaments attached to dense bodies
Attachment of filaments in smooth muscle
Vasculature
Blood supply that differs between slow and fast muscle fibers
Glucose
Carbohydrate metabolized to produce ATP in muscle
Depletion of metabolic reserves
Cause of muscle fatigue
Aging effects on muscle system
Changes in muscle with age, including decrease in diameter and elasticity
Branched
Characteristic of cardiac muscle cells
Single central nucleus
Characteristic of smooth muscle cells
Diameter
Characteristic that differs between slow and fast muscle fibers
Speed of contraction
Characteristic that differs between slow and fast muscle fibers
Fiber type
Classification of muscle fibers based on their characteristics
Structural similarities to skeletal muscle
Comparison between cardiac muscle and skeletal muscle
Muscle fatigue
Condition when muscle can no longer perform at required level of activity
No tendons connected to smooth muscle
Difference between smooth muscle and skeletal muscle
Types of muscle contraction
Different types of muscle contractions
Decrease in tolerance for exercise
Effect of aging on ability to exercise
Ability to recover from injuries decrease
Effect of aging on muscle recovery
Low Ca2+ binding to TnC
Effect of muscle fatigue on calcium binding
Lower enzyme activity
Effect of muscle fatigue on enzyme function
ETC
Electron transport chain, final step in aerobic metabolism of muscle
ATP hydrolysis required for actin myosin interaction
Energy requirement for muscle contraction
ATP
Energy source for muscle contraction
Metabolic substrates
Energy sources that differ between slow and fast muscle fibers
Myosin light chain kinase
Enzyme that activates myosin head in smooth muscle contraction
Types of fibers in an individual
Factors that determine the types of muscle fibers in an individual
Regular exercise more important than extreme exercise
Importance of consistent exercise for muscle health
Ca2+ binds to calmodulin
Interaction between calcium and calmodulin in smooth muscle contraction
Acetyl CoA
Intermediate in aerobic metabolism of muscle
Ca2+
Ions that trigger muscle contraction
Lactate to glucose begins to slow
Metabolic change during muscle fatigue
Intermediate fibers
Muscle fibers suited for both long and short distance activities
Slow fibers
Muscle fibers suited for long distance activities
Fast fibers
Muscle fibers suited for sprinting and short distance activities
Smooth muscle
Muscle type found in organs and blood vessels, under involuntary control
Cardiac muscle
Muscle type found in the heart, similar to skeletal muscle but with structural differences
Conduction system
Network of nodes that allows the heart to contract as a unit
Delayed onset muscle soreness (DOMS)
Pain experienced after exercise, lasting for several days
Krebs cycle
Part of aerobic metabolism that generates ATP in muscle
Myosin head
Part of myosin that attaches to actin during muscle contraction
Autonomic nervous system
Part of the nervous system that controls smooth muscle
Post translation modification
Process that affects muscle function and structure
Fat metabolism
Process that breaks down lipids to produce ATP in muscle
Aerobic metabolism
Process that occurs in mitochondria to produce ATP in muscle
Myoglobin
Protein that stores oxygen in muscle
Hemoglobin
Protein that transports oxygen in red blood cells
Mechanical stretch controls activity
Regulation of single unit smooth muscle contraction
ATP and muscle contraction
Relationship between ATP and muscle contraction
Speed of shortening is inversely proportional to load
Relationship between speed of muscle contraction and load
RQ
Respiratory quotient, ratio of CO2 exhaled to Oxygen used in muscle metabolism
Ca2+ ions trigger contraction
Role of calcium in smooth muscle contraction
Spindle shaped
Shape of smooth muscle cells
Neuromuscular junction
Site where neurotransmitters are released to stimulate muscle contraction
30-200 micrometers
Size range of smooth muscle cells
Carbohydrates
Source of ATP during anaerobic metabolism in muscle
Phosphate group detached from myosin head
Step in smooth muscle contraction
Rigor mortis
Stiffening of muscles after death due to lack of ATP
No T-tubules, microfibrils, or sarcomeres
Structural differences between smooth muscle and skeletal muscle
Intercalated discs
Structures that connect cardiac muscle cells and allow coordinated contraction
Increase in pain
Symptom of muscle fatigue
Eccentric
Type of isotonic contraction where muscle lengthens
Concentric
Type of isotonic contraction where muscle shortens
White meat
Type of meat with more fast twitch fibers
Dark meat
Type of meat with more slow fibers
Isotonic
Type of muscle contraction where muscle length changes
Isometric
Type of muscle contraction where muscle length doesn't change
Multi-unit smooth muscle
Type of smooth muscle found in blood vessels and bronchi, innervated by motor neurons
Single unit smooth muscle
Type of smooth muscle found in digestive and urinary tract, connected through gap junctions
