Lecture 5 Kin PDF - Muscular Strength Training

Summary

This lecture discusses muscular strength, describing various assessment methods and how to train muscles for strength. A case study is also presented.

Full Transcript

2024-10-28

Muscular Strength: Training muscles to
become stronger

Monday October 28, 2024

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Lecture Objectives

Describe four standard methods to assess muscular strength,

Identify how to train muscle to become stronger: describe optimum
sets and repetitions, frequency, and relative intensity for progressive
resistance training,

Understand the adaptations that occur in response to strength
training.
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Case Study

Anthony, a 64 year old physician, comes to you for a strength training
program. He has been inactive since the COVID pandemic - he did
not want to go to the gym due to fear of getting sick. He says he walks
all day long (he works in a hospital) so he only really needs a strength
training program.

Where do you start?
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Anthony’s Path?

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Assessing Muscle Strength
Cable tensiometry; dynamometry; 1-RM; Computer assisted;

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Muscle Strength Measurement

Muscle strength represents the maximum force or tension output
generated by a muscle or related muscle groups
Can be measured by:
Cable tensiometry
Dynamometry
One-repetition maximum
Computer-assisted, electromechanical, and isokinetic methods

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Cable Tensiometry
Increasing force on cable
depresses riser over which the
cable passes
Deflects pointer and
indicates subject’s strength
score
Measures muscle force in a
static or isometric muscle
action that elicits little or no
change in the muscle’s 6

external length
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One-Repetition Maximum

Maximum amount of weight lifted one time using proper form during a
standard weightlifting movement
Difficult to estimate initial weight
Weight progressively added until person reaches maximum lift
capacity
Weight increments range between 1 and 5 kg/2.2 and 11 lb
Rest interval between lifts important

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Dynamometry

External force applied to
dynamometer compresses a
steel spring and moves a
pointer.
The force required to move the
pointer a given distance
determines applied external
force.

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How to estimate 1-RM

Weight lifted for 7 to 10-RM = 68% of 1-RM for untrained and 79% for
trained

Equations to predict 1-RM weight from 7 to 10-RM weight
Untrained: 1-RM (kg) = 1.554 × 7 to 10-RM (kg) – 5.181
Trained: 1-RM (kg) = 1.172 × 7 to 10-RM (kg) – 7.704

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Computer-Assisted, Electromechanical, and
Isokinetic Methods
Force platforms measure the external application of muscle force by a
limb, as in jumping.
Other electromechanical devices assess forces generated during all
phases of an activity (e.g., cycling) or primarily arm (supine bench
press) or leg (leg press) movements.
Isokinetic dynamometer contains a speed-controlling mechanism that
accelerates to a preset, constant velocity with force application.
Measures maximum force generated throughout the full ROM at a pre-
established velocities. 10

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Isokinetic Electromechanical Dynamometer

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Strength-Testing Considerations

Require standardized instructions prior to testing.
Ensure uniformity in duration/intensity of warm-up
Provide adequate practice prior to testing to minimize “learning” effect.
Ensure consistency among subjects in angle of limb measurement
and/or body position on device.
Predetermine a minimum trial number (repetitions) to establish a
criterion strength score.
Select test measures with high reproducibility.
Recognize individual differences in body size and composition when 12
evaluating strength.
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Learning Factors Affect Strength Measures

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Difference in Maximum Weight Lifted Between
Gender

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Training Muscle to Become Stronger
Progressive resistance exercise; Periodization; Isometric Strength Training;
Isokinetic Resistance Training; Plyometric Training

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Resistance Training Equipment Categories

Free weights, kettlebells, and barbells, common weightlifting
equipment

Isokinetic, air pressure, and hydraulic equipment that provides
constant speed and variable resistance

Cam devices and concentric–eccentric apparatus

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Training Muscles to Become Stronger
A muscle strengthens when trained near its current maximum force-
generating capacity.

Overload intensity, not type of exercise that applies overload,
governs strength improvements.

Types of overload applications
Progressive-resistance weight training
Isometric training
Isokinetic training 17

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Different Muscle Actions
Dynamic action produces movement of bones (i.e., upper or lower limb or trunk)
Concentric: occurs when muscle shortens and joint movement occurs as tension
develops

Eccentric: occurs when external resistance exceeds muscle force and muscle
lengthens while developing tension

Static action involves muscle activation without observable change in muscle fiber length
Isometric: occurs when muscle generates force and attempts to shorten but cannot
overcome external resistance
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Concentric, Eccentric and Isometric Actions

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Resistance Training

Most popular form involves raising and lowering an external weight.

Weight lifted remains constant.

Dynamic constant external resistance (DCER)
Barbell
Dumbbell
Weight plates on a pulley- or cam-type machine.

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Progressive Resistance Exercise (PRE)

Novice - 8 to 12-RM, Intermediate - 1 to 12-RM, Advanced- 1 to 6-RM

Rest 3 min between sets

Increase load 2 to 10% when individual performs 1 to 2 repetitions
above current workload

1-set vs 2 to 3 sets ?
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Progressive Resistance Exercise (PRE) (cont.)
Novices and intermediates should train 2 to 3x/wk; advanced can train
3 to 4x/wk.

If training includes multiple exercises, 4 to 5x/wk may produce less
improvement than training 2 to 3x/wk.

Inadequate recovery retards progress in neuromuscular and structural
adaptations and subsequent strength development.

A fast rate of moving resistance generates more strength improvement
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than moving at a slower rate.
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Progressive Resistance Exercise (PRE) (cont.)

Engage large before small muscle groups, multiple-joint exercises
before single-joint exercises, and higher-intensity exercise before
lower-intensity exercise.

Power training should include lighter loads performed at fast
contraction velocity.

In power training, use 2- to 3-min rest intervals between sets.
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Periodization
Subdivides a macrocycle into mesocycles, with each mesocycle
separated into weekly microcycles.
Progressively decreases volume and increases intensity to maximize
strength/power gains
Phases:
Preparation phase: high-volume, low-intensity
First transition phase: moderate volume, moderate intensity
Competition phase: low-volume, high-intensity
Second transition phase: active recovery
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Periodization subdivisions

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Isometric Strength Training

Benefits:
Provides muscle overload
Improves strength
Detects muscle weakness at specific angles in ROM

Limitations:
Poor application for functional sports training
Cannot evaluate overload level or training progress
High degree of specificity 26
Time consuming
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Isometric Training Response Specificity

Training in movements that mimic required force–capacity
improvement

Strength improvement blends two factors:
Neural organization and excitability of motor units power discrete patterns
of voluntary movement
Muscle fiber and connective tissue components

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Muscle Force-Generating Capacity Varies with
Joint Angle

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Isokinetic Resistance Training
Overload muscle at a preset constant speed so muscles fully mobilize
force-generating capacity throughout full ROM,

Effort during exercise movement encounters an opposing force to that
applied by the isokinetic mechanical device,

With an isokinetically loaded muscle, desired movement speed occurs
almost instantaneously while generating the muscle’s peak power
output throughout the ROM.
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Plyometric Training

Various jumps in place or rebound jumping to mobilize inherent
stretch–recoil characteristics of skeletal muscle and its modulation via
the stretch (myotatic) reflex,

Involves rapid stretching followed by muscle-shortening during
dynamic movements,

Plyometric actions overloads muscles, facilitating increases in strength
and power. 30

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Plyometric Training Examples

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Body Weight-Loaded (Closed-Kinetic Chain)
Training
Distal segment bears body weight or part of body weight,

Activates both agonist and antagonist muscles about a joint, including
other muscles groups along the kinetic chain,

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Core Training/Strenghtening (lumbar, trunk or
dynamic.
stabilization, core pillar training)
The “core” represents a four-sided muscular frame with four
components:
Abdominal muscles in front
Paraspinals and gluteals in back
Diaphragm at the top
Pelvic floor and hip girdle musculature frames at the bottom

Includes 29 pairs of muscles that hold trunk steady, and balances and
stabilizes surrounding bony structures 33

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Explosive Power Development

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Anthony’s exercise prescription

Testing?

Exercise training?

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Adaptations that occur
with Strength Training

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Neural and Muscular Adaptations Impact
Strength Improvements
Neural adaptations predominate in the early training phase.

Adaptive alterations in nervous system function that elevate motor
neuron output account for rapid and large strength increases early in
training, without increases in muscle size and cross-sectional area.

Hypertrophy-induced adaptations place the upper limit on longer-term
training improvements.

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Neural and Muscular Adaptations in Strength
Improvement

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Training Impact on Neuromuscular Junction
Nerve conduction velocity (NVC) is faster in the arms than in the legs,
and tapered distal nerve segments conduct more slowly than proximal
segments because they are cooler than proximal regions.

EMG detects neuromuscular abnormalities following a nerve’s
stimulation to a targeted muscle or muscle groups.

EMG and NCV tests help to detect the presence, location, and extent
in nerve and/or muscle dysfunction.
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Changes in Muscle Fiber Size That Accompany
Training-Induced Hypertrophy

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Hypertrophy

Increase in muscular tension (force) with training provides main
stimulus to initiate muscle growth.
Hypertrophy reflects biologic adaptation to increased workload
independent of gender/age.
Overload training enlarges individual fibers with subsequent muscle
growth.
Changes in muscle size become detectable after only 3 wk of
training.
Remodeling of muscle architecture precedes gains in muscle cross-
sectional area.
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Metabolic Adaptations

Strength training enhances anaerobic and aerobic energy transfer
capacity of both fiber types.

Heightened oxidative capacity of fast-twitch fibers with endurance
training brings them to a level nearly equal to the aerobic capacity of
the slow-twitch fibers of untrained counterparts.

Metabolic characteristics of specific fibers and fiber subdivisions
undergo modification within 4 to 8 wk of training. 42

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Fast- and Slow-Twitch Muscle Fiber Ratios

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Muscle Cell Remodeling

Skeletal muscles represent dynamic tissues.
Muscle fibers undergo regeneration and remodeling to alter their
phenotypic profile.
Activation of muscle via specific types and intensities of long-term use
stimulates otherwise dormant myogenic stem cells situated under a
muscle fiber’s basement membrane; these proliferate and differentiate
to form new fibers.
Muscle fiber–type transformations occur with specific-type training.
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Model for Skeletal Muscle Adaptations

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Muscle Plasticity

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Muscle Hyperplasia: Are New Muscle Fibers
Created?
In animals, new fibers develop from satellite cells or by longitudinal
splitting under stress, neuromuscular disease, or muscle injury.

Some evidence supports hyperplasia in humans yet enlargement of
existing individual muscle fibers represents the greatest contribution to
increased muscle size from overload training.

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Changes in Muscle Fiber Type with Resistance
Training
Biopsy data show no change in percentage distribution of fast- and
slow-twitch fibers with resistance training.

Months of resistance training in adults does not alter basic skeletal
muscle fiber composition.

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Muscle Hypertrophy in Men and Women

The absolute amount of muscle hypertrophy with resistance training
represents a primary gender difference.
Men experience a greater absolute change in muscle size from their larger
initial muscle mass.
Muscular enlargement on a percentage basis remains similar between
genders.

Gender-related differences in hormonal response to resistance
exercise may determine any ultimate gender differences in muscle
size and strength adaptations with prolonged training. 49

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Special Considerations

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Resistance Training Guidelines for Health
Enhancement and Disease Prevention
Competitive athletes
Optimize muscular strength, power, and hypertrophy with high
intensity
1-RM to 6-RM

Middle-aged and older adults
Focus on maintenance of muscle and bone mass and muscular
strength and muscular endurance to enhance overall health and
physical-fitness
Moderate intensity 8-15 RM; 2× week 51

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Resistance Training for Children

Supervised resistance training using concentric-only muscle actions
with relatively high repetitions and low resistance,

Concerns for potential injury from excessive musculoskeletal loading
include epiphyseal fractures, ruptured intervertebral disks, lower back
bony disruptions, and acute back trauma.

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Does Resistance Training Plus Aerobic Training
Equal Less Strength Improvement?
Combining different modes of exercise may induce antagonistic
molecular level, intracellular signaling mechanisms that could
negatively impact,

Added energy (and perhaps protein) demands of aerobic training
limit a muscle’s growth and metabolic responsiveness to resistance
training muscle’s adaptive response to resistance training,

Aerobic training may also inhibit signaling to the muscles’ protein- 53
synthesis machinery
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Factors That Interact to Develop and Maintain
Muscle Mass

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Resistance Training and Metabolic Stress

Resistance training produces no improvement in VO2max or
submaximal exercise HR and SV.
Lack of cardiovascular improvement probably results from the
relatively low “whole body” metabolic and circulatory demands and
high anaerobic metabolic requirements of resistance training.
Light-to-moderate HR response (≤130 b·min−1) occurs with 8- to 10-
RM weightlifting exercises, and elicits an energy expenditure of only 3
to 4 METs.
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Detraining Effects on Muscle

Limited data document that muscle strength decrements and
associated factors with cessation of resistance training conclude that:

Discontinuing training for 2 wk caused male power lifters to lose 12% of
their isokinetic eccentric muscle strength and 6.4% of their type II muscle
fiber area, without loss in type I fiber area.

Reducing training frequency to 1 to 2 weekly sessions provides sufficient
stimulus to maintain training-induced strength gains
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Circuit Resistance Training (CRT)

Deemphasizes brief intervals of heavy, local-muscle overload in
standard resistance training in favor of more prolonged submaximal
effort
Provides more general conditioning that improves body composition,
muscular strength and endurance, and cardiovascular fitness
A person lifts a weight between 40 to 55% of 1-RM
as many times as possible with good form for 30 s
After a 15-s rest, person moves to next exercise
station and so on to complete the circuit, usually composed of 8 to 57
15 stations.
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Delayed Onset Muscle Soreness and Stiffness

Occurs following extended layoffs or with unaccustomed exercise
Appears later and can last for 3 to 4 days; termed delayed-onset
muscle soreness or DOMS
Factors that can produce DOMS
Minute tears in muscle tissue
Osmotic pressure changes
Muscle spasms
Overstretching and tearing of portions of connective tissue harness
Acute inflammation 58
Alteration in the cell's calcium regulation
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Delayed-Onset Muscle Soreness (DOMS)
Eccentric muscle actions induce greater DOMS than concentric-only
or isometric actions, particularly in older adults.
Existing muscle damage or soreness from previous activity does not
exacerbate subsequent muscle damage or impair the repair
process.
The body initiates a series of adaptive cellular events to
unaccustomed exercise that produces DOMS.
Alterations in sarcoplasmic reticulum structure and function with
unaccustomed physical activity can cause alterations in pH,
intramuscular high-energy phosphates, ionic balance, temperature 59

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Phases in DOMS
Development
and Healing:

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Muscle Soreness Ratings

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Questions?

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