Adaptations to Resistance Training PDF

Summary

This document provides a comprehensive overview of adaptations to resistance training, such as muscle growth and neural adjustments. It explains the process of muscular hypertrophy and the interplay between training and diet. 

Full Transcript

Adaptations to
Resistance Training

CHAPTER 11 Overview
• Resistance training and gains in muscular
fitness
• Mechanisms of gains in muscle strength
• Interaction between resistance training and
diet
• Resistance training for special populations

Resistance Training:
Introduction
• Substantial strength gains via
neuromuscular changes
• Important for overall fitness and health
• Critical for athletic training programs

Resistance Training:
Gains in Muscular Fitness
• After 3 to 6 months of resistance training
– 25% to 100% strength gain
– Better force production
– Ability to produce true maximal movement

• Similar strength gains as percentage of
initial strength
– But greater absolute gains for young men than for
young women, older men, or children
– Due to incredible muscle plasticity

Mechanisms of Muscle Strength Gain
• Hypertrophy versus atrophy

– muscle size  muscle strength
– muscle size  muscle strength
– But association more complex than that

• Sources of strength gains
– muscle size
– Altered neural control

Figure 11.1a

Figure 11.1b

Figure 11.1c

Mechanisms of Muscle Strength Gain:
Neural Control
• Strength gain cannot occur without neural
adaptations via plasticity.
– Strength gain can occur without hypertrophy.
– Strength is a property of the motor system, not just
of muscle.

• Essential elements include motor unit
recruitment, stimulation frequency, and
other neural factors.

Mechanisms of Muscle Strength Gain:
Motor Unit Recruitment (1 of 2)
• Motor units normally recruited
asynchronously
• Synchronous recruitment  strength gains
– Facilitates contraction.
– May produce more forceful contraction.
– Improves rate of force development.
– Improves capability to exert steady forces.

• Resistance training  synchronous
recruitment

(continued)

Mechanisms of Muscle Strength Gain:
Motor Unit Recruitment (2 of 2)
• Strength gains may also result from greater
motor unit recruitment.
–
–
–

neural drive during maximal contraction
frequency of neural discharge (rate coding)
inhibitory impulses

• Likely that a combination of improved motor
unit synchronization and motor unit
recruitment leads to strength gains.

Mechanisms of Muscle Strength Gain:
Motor Unit Rate Coding
• Limited evidence suggests that rate coding
increases with resistance training,
especially rapid-movement, ballistic-type
training.

Mechanisms of Muscle Strength Gain:
Autogenic Inhibition
• Normal intrinsic inhibitory mechanisms
– Example: Golgi tendon organs.
– Inhibit muscle contraction if tendon tension too high.
– Prevent damage to bones and tendons.

• Inhibitory impulses  by training
– Muscle can generate more force.
– May also explain superhuman feats of strength.

Mechanisms of Muscle Strength Gain:
Other Neural Factors
• Coactivation of agonists, antagonists
– Normally antagonists oppose agonist force.
– Reduced coactivation may  strength gain.

• Morphology of neuromuscular junction

Mechanisms of Muscle Strength Gain:
Muscle Hypertrophy
• Hypertrophy: increase in muscle size
• Transient hypertrophy (after exercise bout)
– Due to edema formation from plasma fluid
– Gone within hours

• Chronic hypertrophy (long term)
– Structural change in muscle
– Fiber hypertrophy, fiber hyperplasia, or both

Figure 11.2a

Figure 11.2b

Mechanisms of Muscle Strength Gain:
Chronic Muscle Hypertrophy
• Maximized by high-velocity eccentric
training, which disrupts sarcomere Z-lines
(protein remodeling).
• Concentric training may limit muscle
hypertrophy, strength gains.
• Stimulated by intensities as low as 30%
1RM and as high as 90%.
• Caused by both high-rep (low-load) and lowrep (high-load) training.

Mechanisms of Muscle Strength Gain:
Fiber Hypertrophy
•
•
•
•
•

More myofibrils
More actin, myosin filaments
More sarcoplasm
More connective tissue
Resistance training  protein synthesis
– Muscle protein content always changing
– During exercise: synthesis , degradation
– After exercise: synthesis , degradation

Mechanisms of Muscle Strength Gain:
Hormones and Hypertrophy
• Fiber hypertrophy facilitated by testosterone
– Natural anabolic steroid hormone
– Synthetic anabolic steroids  large increases in
muscle mass

• Growth hormone (GH)
• Insulin-like growth factor 1 (IGF-1)
• Elevated postexercise levels not required for
anabolism and strength

Mechanisms of Muscle Strength Gain:
Fiber Hyperplasia (1 of 3)
• Cats
– Intense strength training produces fiber splitting.
– Each half grows to size of parent fiber.

• Chickens, mice, rats
– Intense strength training produces only fiber
hypertrophy.
– But difference may be due to training regimen.
(continued)

Figure 11.3

Mechanisms of Muscle Strength Gain:
Fiber Hyperplasia (2 of 3)
• Humans
– Most hypertrophy is due to fiber hypertrophy.
– Fiber hyperplasia also contributes.
– Fiber hypertrophy versus fiber hyperplasia may
depend on resistance training intensity or load.
– Higher intensity causes (type II) fiber hypertrophy.

• Fiber hyperplasia may occur only in certain
individuals under certain conditions.
(continued)

Mechanisms of Muscle Strength Gain:
Fiber Hyperplasia (3 of 3)
• Can occur through fiber splitting.
• Also occurs through satellite cells.
– Myogenic stem cells involved in skeletal muscle
regeneration
– Activated by stretch, injury
– After activation: proliferate, migrate, fuse

Figure 11.4

Animation 11.4

For audio description use this link:
https://players.brightcove.net/901973548001/kplGlX8REA_default/index.html?videoId=6263541
048001

Mechanisms of Muscle Strength Gain:
Neural Activation and Hypertrophy
• Short-term

in muscle strength

• Long-term

in muscle strength

– Substantial in 1RM
– Due to voluntary neural activation
– Neural factors critical in first 8 to 10 weeks
– Associated with significant fiber hypertrophy
– Net protein synthesis requiring time to occur
– Hypertrophy major factor after first 10 weeks

Mechanisms of Muscle Strength Gain:
Atrophy and Inactivity
• Reduction or cessation of activity  major
change in muscle structure and function
• Limb immobilization studies
• Detraining studies

Mechanisms of Muscle Strength Gain:
Immobilization
• Major changes after 6 h

– Lack of muscle use  reduced protein synthesis.
– Initiates process of muscle atrophy.

• First week: strength loss of 3%-4% per day
–
–

size (atrophy)
neuromuscular activity

• (Reversible) effects on type I and II fibers

– Cross-sectional area , cell contents degenerate.
– Type I is affected more than type II.

Mechanisms of Muscle Strength Gain:
Detraining
• Leads to

in 1RM.

– Lost strength can be regained (~6 weeks).
– New 1RM matches or exceeds old 1RM.

• Once training goal met, maintenance
resistance program prevents detraining.
– Maintain strength and 1RM.
– Reduce training frequency.

Figure 11.6

Mechanisms of Muscle Strength Gain:
Fiber Type Alterations (1 of 2)
• Training regimen may not outright change
fiber type, but . . .
– Type II fibers more oxidative with aerobic training
– Type I fibers more anaerobic with anaerobic training

• Fiber type conversion is possible under
certain conditions.
– Cross-innervation
– Chronic low-frequency stimulation
– High-intensity treadmill or resistance training
(continued)

Mechanisms of Muscle Strength Gain:
Fiber Type Alterations (2 of 2)
• Type IIx  type IIa transition common
• 20-week heavy resistance training program:
– Static strength, cross-sectional area
– Percentage type IIx , percentage type IIa

• Other studies: type I  type IIa with highintensity resistance work + short-interval
speed work

Interaction Between
Resistance Training and Diet
• Resistance training increases protein synthesis.
• Consume 20 to 25 g protein after resistance exercise
for muscle growth.
• Consume 1.6 to 1.7 g protein per kg body weight per
day to increase muscle mass.
• Small doses (20 g) every 2 to 3 hours are
recommended for protein synthesis.
• Larger doses (20-25 g) recommended immediately
after resistance training.

Molecular Mechanisms of Increased
Protein Synthesis
• Repeated muscle stretch → ↑ IGF-1
• ↑ IGF-1 → ↑ mTOR
– Integrates input from insulin, growth factors, amino
acids.
– Dictates transcription of mRNA.
– Synthesizes ribosomes.

• Stimulated by insulin
• Translation
– Amino acids converted into protein via mRNA.

Figure 11.7

Figure 11.8

Animation 11.8

For audio description use this link:
https://players.brightcove.net/901973548001/kplGlX8REA_default/index.html?videoId=6259867
027001

Video 11.1

Resistance Training for
Special Populations: Age
• Children and adolescents
– Myth: Resistance training is unsafe due to growth
plate, hormonal changes.
– Truth: It is safe with proper safeguards.
– Children can gain both strength and muscle mass.

• Elderly persons
– Helps restore age-related loss of muscle mass.
– Improves quality of life and health.
– Helps prevent falls.

Strength Training in Older Adults
• Increases in strength dependent primarily
on neural adaptations
– No difference across sex or race

• Same response as in younger but blunted
– Decreased mTOR signaling response
– Smaller increases in myofibrillar protein and muscle
size
– 25-50 g protein necessary to stimulate muscle
protein synthesis

Resistance Training for Sport
• Training is not worth it beyond the basic
strength, power, and endurance needs of
the chosen sport.
• Training costs valuable time.
• Training results should be tested with sportspecific performance metrics.