Muscle Performance and Resistance Exercise PDF

Summary

This document discusses muscle performance and resistance exercise. It covers definitions, guiding principles, different exercise types, and the positive impact of resistance training on strength, power, and endurance. The document also addresses the benefits of exercise for various purposes and how it impacts daily life and professional health.

Full Transcript

*Muscle performance* refers to the capacity of a muscle to do

work (force × distance).11 Despite the simplicity of the definition,

muscle performance is a complex component of functional

movement and is influenced by all of the body systems.

Factors that affect muscle performance include the morphological

qualities of muscle; neurological, biochemical, and

biomechanical influences; and metabolic, cardiovascular,

respiratory, cognitive, and emotional function. For a person

to anticipate, respond to, and control the forces applied to

the body and carry out the physical demands of everyday life

in a safe and efficient manner, the body's muscles must be

able to produce, sustain, and regulate muscle tension to meet

these demands.

The key elements of muscle performance are *strength*,

*power*, and *endurance*.11 If any one or more of these areas of

muscle performance is impaired, activity limitations (functional

limitations) and participation restriction (disability)

or increased risk of dysfunction may ensue. Many factors,

such as injury, disease, immobilization, disuse, and inactivity,

may result in impaired muscle performance, leading to weakness

and muscle atrophy. When deficits in muscle performance

place a person at risk for injury or hinder function, the

use of resistance exercise is an appropriate therapeutic intervention

to improve the integrated use of strength, power,

and muscular endurance during functional movements, to

reduce the risk of injury or re-injury, and to enhance physical

performance.

*Resistance exercise* is any form of active exercise in which

dynamic or static muscle contraction is resisted by an outside

force applied manually or mechanically.103,248 Resistance exercise,

also referred to as *resistance training*,8,9,167 is an essential

element of rehabilitation programs for persons with impaired

function and an integral component of conditioning programs

for those who wish to promote or maintain health and

physical well-being, potentially enhance performance of

motor skills, and reduce the risk of injury and disease.8,9,242

A comprehensive examination and evaluation of a patient

or client are the foundations on which a therapist determines

whether a program of resistance exercise is warranted and

can improve a person's current level of function or prevent

potential dysfunction. Many factors influence how appropriate,

effective, or safe resistance training is and how the exercises

are designed, implemented, and progressed. Factors, such as

the underlying pathology; the extent and severity of muscle

performance impairments; the presence of other deficits; the

stage of tissue healing after injury or surgery; and a patient's

or client's age, overall level of fitness, and ability to cooperate

and learn, all must be considered. Once a program of resistance

exercise is developed and prescribed to meet specific functional

goals and outcomes, direct intervention by a therapist initially

to implement the exercise program or to begin to teach and

supervise the prescribed exercises for a smooth transition to

an independent, home-based program is imperative.

This chapter provides a foundation of information on

resistance exercise, identifies the determinants of resistance

training programs, summarizes the principles and guidelines

for application of manual and mechanical resistance exercise,

and explores a variety of regimens for resistance training. It

also addresses the scientific evidence, when available, of the

relationship between improvements in muscle performance

and enhanced functional abilities. The specific techniques

described and illustrated in this chapter focus on manual resistance

exercise for the extremities, primarily used during the

early phase of rehabilitation. Additional exercises performed

independently by a patient or client using resistance equipment

are described and illustrated in Chapters 17 through 23.

The use of resistance exercise for spinal conditions is presented

in Chapter 16.

**Muscle Performance**

**and Resistance Exercise:**

**Definitions and Guiding**

**Principles**

The three elements of muscle performance11---strength,

power, and endurance---can be enhanced by some form of

resistance exercise. To what extent each of these elements is

altered by exercise depends on how the principles of resistance

training are applied and how factors such as the intensity,

frequency, and duration of exercise are manipulated. Because

the physical demands of work, recreation, and everyday living

usually involve all three aspects of muscle performance, most

resistance training programs seek to achieve a balance of

strength, power, and muscular endurance to suit an individual's

needs and goals. In addition to having a positive impact on

muscle performance, resistance training can produce many

other benefits.8-10 These potential benefits are listed in

Box 6.1. After a brief description of the three elements of

muscle performance, guiding principles of exercise prescription

and training are discussed in this section.

**Strength, Power, and Endurance**

**Strength**

*Muscle strength* is a broad term that refers to the ability of

contractile tissue to produce tension and a resultant force

based on the demands placed on the muscle.182,192,210 More

specifically, muscle strength is the greatest measurable force

that can be exerted by a muscle or muscle group to overcome

resistance during a *single* maximum effort.11 *Functional*

*strength* relates to the ability of the neuromuscular system

to produce, reduce, or control forces, contemplated or imposed,

during functional activities, in a smooth, coordinated

manner.42,219 Insufficient muscular strength can contribute

to major functional losses of even the most basic activities of

daily living.

***Strength training.*** The development of muscle strength is

an integral component of most rehabilitation or conditioning

**158** Muscle Performance and Resistance Exercise: Definitions and
Guiding Principles

programs for individuals of all ages and all ability levels.

8,10,90,168,221 *Strength training* (*strengthening exercise*) is

defined as a systematic procedure of a muscle or muscle group

lifting, lowering, or controlling heavy loads (resistance) for a

relatively low number of repetitions or over a short period of

time.9,31,103 The most common adaptation to heavy resistance

exercise is an increase in the maximum force-producing

capacity of muscle---that is, an increase in muscle strength,

primarily as the result of neural adaptations and an increase

in muscle fiber size.9,10,192

**Power**

*Muscle power*, another aspect of muscle performance, is related

to the strength and speed of movement and is defined

as the work (force × distance) produced by a muscle per unit

of time (force × distance/time).11,182,192,210 In other words, it

is the *rate* of performing work. The rate at which a muscle

contracts and produces a resultant force and the relationship

of force and velocity are factors that affect muscle power.31,210

Because work can be produced over a very brief or an extended

period of time, power can be expressed by either a

single burst of high-intensity activity (such as lifting a heavy

piece of luggage onto an overhead rack or performing a

high jump) or by repeated bursts of less intense muscle

activity (such as climbing a flight of stairs). The terms *anaerobic*

*power* and *aerobic power*, respectively, are sometimes used

to differentiate these two aspects of power.192

***Power training.*** Many motor skills in our lives are composed

of movements that are explosive and involve both

strength and speed. Therefore, re-establishing muscle power

may be an important priority in a rehabilitation program.

Muscle strength is a necessary foundation for developing

muscle power. Power can be enhanced by either increasing

the work a muscle must perform during a specified period of

time or reducing the amount of time required to produce a

given force. The greater the intensity of the exercise and the

shorter the time period taken to generate force, the greater

is the muscle power. For power training regimens, such as

*plyometric training* or *stretch-shortening drills*, the speed of

movement is the variable that is most often manipulated293

(see Chapter 23).

**Endurance**

Endurance is a broad term that refers to the ability to perform

low-intensity, repetitive, or sustained activities over a

prolonged period of time. *Cardiopulmonary endurance* (*total*

*body endurance*) is associated with repetitive, dynamic

motor activities, such as walking, cycling, swimming, or

upper extremity ergometry, which involve use of the large

muscles of the body.8,9 This aspect of endurance is explored

in Chapter 7.

*Muscle endurance* (sometimes referred to as *local endurance*)

is the ability of a muscle to contract repeatedly against a

load (resistance), generate and sustain tension, and resist

fatigue over an extended period of time.8,9,11,234 The term

*aerobic power* sometimes is used interchangeably with

muscle endurance. Maintenance of balance and proper

alignment of the body segments requires sustained control

(endurance) by the postural muscles. In fact, almost all daily

living tasks require some degree of muscle and cardiopulmonary

endurance.

Although strength and muscle endurance, as elements

of muscle performance, are associated, they do not always

correlate well with each other. Just because a muscle group is

strong, it does not preclude the possibility that muscular

endurance is impaired. For example, a strong worker has no

difficulty lifting a 10-pound object several times, but does

the worker have sufficient muscle endurance in the upper

extremities and the stabilizing muscles of the trunk and lower

extremities to lift 10-pound objects several hundred times

during the course of a day's work without excessive fatigue or

potential injury?

***Endurance training.** Endurance training* (*endurance exercise*)

is characterized by having a muscle contract and lift or

lower a light load for many repetitions or sustain a muscle

contraction for an extended period of time.9,10,192,210,260 The

key parameters of endurance training are low-intensity

muscle contractions, a large number of repetitions, and a

prolonged time period. Unlike strength training, muscles

adapt to endurance training by increases in their oxidative

and metabolic capacities, which allows better delivery and

use of oxygen. For many patients with impaired muscle

performance, endurance training has a more positive impact

on improving function than strength training. In addition,

using low levels of resistance in an exercise program minimizes

adverse forces on joints, produces less irritation to

soft tissues, and is more comfortable than heavy resistance

exercise.

**CHAPTER 6** Resistance Exercise for Impaired Muscle Performance
**159**

**BOX 6.1 Potential Benefits of Resistance**

**Exercise**

Enhanced muscle performance: restoration, improvement

or maintenance of muscle strength, power, and endurance

Increased strength of connective tissues: tendons,

ligaments, intramuscular connective tissue

Greater bone mineral density or less bone demineralization

Decreased stress on joints during physical activity

Reduced risk of soft tissue injury during physical activity

Possible improvement in capacity to repair and heal

damaged soft tissues due to positive impact on tissue

remodeling

Possible improvement in balance

Enhanced physical performance during daily living,

occupational, and recreational activities

Positive changes in body composition: ↑ lean muscle mass

or ↓ body fat

Enhanced feeling of physical well-being

Possible improvement in perception of disability and quality

of life

**Overload Principle**

**Description**

The overload principle is a guiding principle of exercise

prescription that has been one of the foundations on which

the use of resistance exercise to improve muscle performance

is based. Simply stated, if muscle performance is to improve,

a load that exceeds the metabolic capacity of the muscle

must be applied---that is, the muscle must be challenged

to perform at a level greater than that to which it is accustomed.

9,10,128,168,192,206 If the demands remain constant after

the muscle has adapted, the level of muscle performance can

be maintained but not increased.

**Application of the Overload Principle**

The overload principle focuses on the progressive loading of

muscle by manipulating, for example, the intensity or volume

of exercise. Intensity of resistance exercise refers to how much

weight (resistance) is imposed on the muscle, whereas volume

encompasses variables such as repetitions, sets, or frequency

of exercise, any one or more of which can be gradually

adjusted to increase the demands on the muscle.

In a strength training program, the amount of resistance

applied to the muscle is incrementally and progressively

increased.

For endurance training, more emphasis is placed on increasing

the *time* a muscle contraction is sustained or the *number*

*of repetitions* performed than on increasing resistance.

**PRECAUTION:** To ensure safety, the extent and progression

of overload must always be applied in the context of the

underlying pathology, age of the patient, stage of tissue healing,

fatigue, and the overall abilities and goals of the patient. The

muscle and related body systems must be given time to *adapt*

to the demands of an increased load or repetitions before the

load or number of repetitions is again increased.

**SAID Principle**

The SAID principle (specific adaptation to imposed demands)

9,192 suggests that a framework of specificity is a

necessary foundation on which exercise programs should be

built. This principle applies to all body systems and is an

extension of Wolff's law (body systems adapt over time to the

stresses placed on them). The SAID principle helps therapists

determine the exercise prescription and which parameters of

exercise should be selected to create specific training effects

that best meet specific functional needs and goals.

**Specificity of Training**

Specificity of training, also referred to as specificity of exercise,

is a widely accepted concept suggesting that the adaptive

effects of training, such as improvement of strength, power,

and endurance, are highly specific to the training method employed.

9,183 Whenever possible, exercises incorporated in a

program should mimic the anticipated function. For example,

if the desired functional activity requires greater muscular

endurance than strength, the intensity and duration of

exercises should be geared to improve muscular endurance.

Specificity of training also should be considered with respect

to mode (type) and velocity of exercise24,80,205,225 as well

as patient or limb position (joint angle)161,162,285 and the

movement pattern during exercise. For example, if the desired

functional outcome is the ability to ascend and descend stairs,

exercise should be performed eccentrically and concentrically

in a weight-bearing pattern and progressed to the desired

speed. Regardless of the simplicity or complexity of the motor

task to be learned, task-specific practice always must be

emphasized. It has been suggested that the basis of specificity

of training is related to morphological and metabolic changes

in muscle as well as neural adaptations to the training

stimulus associated with motor learning.218

**Transfer of Training**

In contrast to the SAID principle, carryover of training effects

from one variation of exercise or task to another also has been

reported. This phenomenon is called transfer of training,

overflow, or a cross-training effect. Transfer of training has

been reported to occur on a very limited basis with respect to

the velocity of training143,273 and the type or mode of exercise.80

Furthermore, it has been suggested that a cross-training

effect can occur from an exercised limb to a nonexercised,

contralateral limb in a resistance training program.283,284

A program of exercises designed to develop muscle

strength also has been shown to improve muscular endurance

at least moderately. In contrast, endurance training has little

to no cross-training effect on strength.9,18,103 Strength training

at one speed of exercise has been shown to provide some

improvement in strength at higher or lower speeds of exercise.

However, the overflow effects are substantially less than the

training effects resulting from specificity of training.

Despite the evidence that a small degree of transfer of

training does occur in a resistance exercise program, most

studies support the importance of designing an exercise

program that most closely replicates the desired functional

activities. As many variables as possible in the exercise program

should match the requirements and demands placed on a

patient during specific functional activities.

**Reversibility Principle**

Adaptive changes in the body's systems, such as increased

strength or endurance, in response to a resistance exercise

program are transient unless training-induced improvements

are regularly used for functional activities or unless an individual

participates in a maintenance program of resistance

exercises.8,9,46,89,192

*Detraining,* reflected by a reduction in muscle performance,

begins within a week or two after the cessation of resistance

exercises and continues until training effects are

lost.9,89,167,207 For this reason, it is imperative that gains in

strength and endurance are incorporated into daily activities

as early as possible in a rehabilitation program. It is also

**160** Muscle Performance and Resistance Exercise: Definitions and
Guiding Principles

advisable for patients to participate in a maintenance program

of resistance exercises as an integral component of a lifelong

fitness program.

**Skeletal Muscle Function**

**and Adaptation to Resistance**

**Exercise**

Knowledge of the factors that influence the force-producing

capacity of normal muscle during an active contraction is

fundamental to understanding how the neuromuscular system

adapts as the result of resistance training. This knowledge, in

turn, provides a basis on which a therapist is able to make sound

clinical decisions when designing resistance exercise programs

for patients with weakness and functional limitations as the

result of injury or disease or to enhance physical performance

and prevent or reduce the risk of injury in healthy individuals.

**Factors that Influence Tension**

**Generation in Normal Skeletal Muscle**

**NOTE:** For a brief review of the structure of skeletal muscle,

refer to Chapter 4 of this textbook. For in-depth information on

muscle structure and function, numerous resources are

available.182,183,192,210

Diverse but interrelated factors affect the tension-generating

capacity of *normal* skeletal muscle necessary to control

the body and perform motor tasks. Determinants and correlates

include morphological, biomechanical, neurological,

metabolic, and biochemical factors. All contribute to the

*magnitude, duration,* and *speed* of force production as well as

how resistant or susceptible a muscle is to fatigue. Properties

of muscle itself and as key neural factors and their impact on

tension generation during an active muscle contraction are

summarized in Table 6.1. 9,182,183,192,210

Additional factors---such as the energy stores available to

muscle, the influence of fatigue and recovery from exercise,

and a person's age, gender, and psychological/cognitive status,

as well as many other factors---affect a muscle's ability to

develop and sustain tension. A therapist must recognize that

these factors affect a patient's performance during exercise as

well as the potential outcomes of the exercise program.

**Energy Stores and Blood Supply**

Muscle needs adequate sources of energy (fuel) to contract,

generate tension, and resist fatigue. The predominant fiber

type found in the muscle and the adequacy of blood supply,

which transports oxygen and nutrients to muscle and removes

waste products, affect the tension-producing capacity of a

**CHAPTER 6** Resistance Exercise for Impaired Muscle Performance
**161**

The larger the muscle diameter, the greater its

tension-producing capacity.

Short fibers with pinnate and multipinnate design in high

force-producing muscles (ex. quadriceps, gastrocnemius,

deltoid, biceps brachii).

Long, parallel design in muscles with high rate of shortening

but less force production (ex. sartorius, lumbricals).

High percentage of type I fibers---low force production, slow

rate of maximum force development, resistant to fatigue.

High percentage of type IIA and IIB fibers---rapid high force

production; rapid fatigue.

Muscle produces greatest tension when it is near or at the

physiological resting length at the time of contraction.

The greater the number and synchronization of motor units

firing, the greater the force production.

The higher the frequency of firing, the greater the tension.

Force output from greatest to least---eccentric, isometric,

concentric muscle contraction.

Concentric contraction: ↑ speed → ↓ tension. Eccentric

contraction: ↑ speed → ↑ tension.

**TABLE 6.1** Determinants and Correlates that Affect Tension Generation
of Skeletal Muscle

**Factor Influence**

Cross-section and size of the muscle (includes muscle

fiber number and size)

Muscle architecture---fiber arrangement and fiber length

(also relates to cross-sectional diameter of the muscle)

Fiber-type distribution of muscle---type I (tonic,

slow-twitch) and type IIA & IIB (phasic, fast-twitch)

Length-tension relationship of muscle at time of contraction

Recruitment of motor units

Frequency of firing of motor units

Type of muscle contraction

Speed of muscle contraction (force-velocity relationship)

muscle and its resistance to fatigue. The three main energy

systems (ATP-PC system, anaerobic/glycolytic/lactic acid

system, aerobic system) are reviewed in Chapter 7.

**Fatigue**

Fatigue is a complex phenomenon that affects muscle performance

and must be considered in a resistance exercise

program. Fatigue has a variety of definitions that are based

on the type of fatigue being addressed.

***Muscle (local) fatigue.*** Most relevant to resistance exercise

is the phenomenon of skeletal muscle fatigue. Muscle (local)

fatigue---the diminished response of muscle to a repeated

stimulus---is reflected in a progressive decrement in the

amplitude of motor unit potentials.183,192 This occurs during

exercise when a muscle repeatedly contracts statically or

dynamically against an imposed load.

This *acute* physiological response to exercise is *normal*

and *reversible.* It is characterized by a gradual decline in the

force-producing capacity of the neuromuscular system---that

is, a *temporary* state of exhaustion (failure), leading to a

decrease in muscle strength.23,56,183,253

The diminished response of the muscle is caused by a

complex combination of factors, which include disturbances

in the contractile mechanism of the muscle itself (associated

with a decrease in energy stores, insufficient oxygen, reduced

sensitivity and availability of intracellular calcium, and a

build-up of H+) and perhaps reduced excitability at the

neuromuscular junction or inhibitory (protective) influences

from the central nervous system.183,192,210

The fiber-type distribution of a muscle, which can be

divided into two broad categories (type I and type II),

affects how resistant it is to fatigue.183,192,210 Type II (phasic,

fast-twitch) muscle fibers are further divided into two

additional classifications (types IIA and IIB) based on contractile

and fatigue characteristics. Some resources subdivide

type II fibers into three classifications.239 In general, type II

fibers generate a great amount of tension within a short

period of time, with type IIB being geared toward anaerobic

metabolic activity and having a tendency to fatigue more

quickly than type IIA fibers. Type I (tonic, slow-twitch)

muscle fibers generate a low level of muscle tension but can

sustain the contraction for a long time. These fibers are

geared toward aerobic metabolism, as are type IIA fibers.

However, type I fibers are more resistant to fatigue than

type IIA. Table 6.2 compares the characteristics of muscle

fiber types.9,182,183,210

Because different muscles are composed of varying proportions

of tonic and phasic fibers, their function becomes

specialized. For example, a heavy distribution of type I (slow

twitch, tonic) fibers is found in postural muscles, which allows

muscles, such as the soleus, to sustain a low level of tension

for extended periods of time to hold the body erect against

gravity or stabilize against repetitive loads. On the other end

of the fatigue spectrum, muscles with a large distribution of

type IIB (fast twitch, phasic) fibers, such as the gastrocnemius

or biceps brachii, produce a great burst of tension to enable a

person to lift the entire body weight or to lift, lower, push, or

pull a heavy load but fatigue quickly.

Clinical signs of muscular fatigue during exercise are summarized

in Box 6.2.192,210 When these signs and symptoms

develop during resistance exercise, it is time to decrease the

load on the exercising muscle or stop the exercise and shift to

another muscle group to allow time for the fatigued muscle

to rest and recover.

***Cardiopulmonary (general) fatigue.*** This type of fatigue

is the diminished response of an individual (the entire body)

as the result of prolonged physical activity, such as walking,

jogging, cycling, or repetitive lifting or digging. It is related to

the body's ability to use oxygen efficiently. Cardiopulmonary

fatigue associated with endurance training is probably caused

by a combination of the following factors.23,114

Decrease in blood sugar (glucose) levels.

Decrease in glycogen stores in muscle and liver.

Depletion of potassium, especially in the elderly patient.

**162** Skeletal Muscle Function and Adaptation to Resistance Exercise

**TABLE 6.2** Muscle Fiber Types and Resistance

to Fatigue

**Characteristics Type I Type IIA Type IIB**

Resistance High Intermediate Low

to fatigue

Capillary density High High Low

Energy system Aerobic Aerobic Anerobic

Diameter Small Intermediate Large

Twitch rate Slow Fast Fast

Maximum Slow Fast Fast

muscle-shortening

velocity

**BOX 6.2 Signs and Symptoms of Muscle**

**Fatigue**

An uncomfortable sensation in the muscle, even pain and

cramping

Tremulousness in the contracting muscle

An unintentional slowing of movement with successive

repetitions of an exercise

Active movements: jerky, not smooth

Inability to complete the movement pattern through the full

range of available motion during dynamic exercise against

the same level of resistance

Use of substitute motions---that is, incorrect movement

patterns---to complete the movement pattern

Inability to continue low-intensity physical activity

Decline in peak torque during isokinetic testing

***Threshold for fatigue.*** Threshold for fatigue is the level of

exercise that cannot be sustained indefinitely.23 A patient's

threshold for fatigue could be noted as the length of time a

contraction is maintained or the number of repetitions of an

exercise that initially can be performed. This sets a baseline

from which adaptive changes in physical performance can be

measured.

***Factors that influence fatigue.*** Factors that influence fatigue

are diverse. A patient's health status, diet, or lifestyle (sedentary

or active) all influence fatigue. In patients with neuromuscular,

cardiopulmonary, inflammatory, cancer-related, or psychological

disorders, the onset of fatigue is often abnormal.4,56,98

For instance, it may occur abruptly, more rapidly, or at

predictable intervals.

It is advisable for a therapist to become familiar with the

patterns of fatigue associated with different diseases and

medications. In multiple sclerosis, for example, the patient

usually awakens rested and functions well during the early

morning. By mid-afternoon, however, the patient reaches a

peak of fatigue and becomes notably weak. Then, by early

evening, the fatigue diminishes and strength returns. Patients

with cardiac, peripheral vascular, and pulmonary diseases, as

well as patients with cancer undergoing chemotherapy or

radiation therapy, all have deficits that compromise the oxygen

transport system. Therefore, these patients fatigue more

readily and require a longer period of time for recovery from

exercise.4,98

Environmental factors, such as outside or room temperature,

air quality, and altitude, also influence how quickly the

onset of fatigue occurs and how much time is required for

recovery from exercise.169,192

**Recovery from Exercise**

Adequate time for recovery from fatiguing exercise must be

built into every resistance exercise program. This applies to

both intrasession and intersession recovery. After vigorous

exercise, the body must be given time to restore itself to a state

that existed prior to the exhaustive exercise. Recovery from

acute exercise, in which the force-producing capacity of

muscle returns to 90% to 95% of the pre-exercise capacity,

usually takes 3 to 4 minutes, with the greatest proportion of

recovery occurring in the first minute.51,244

During recovery oxygen and energy stores are replenished

quickly in muscles. Lactic acid is removed from skeletal muscle

and blood within approximately 1 hour after exercise, and

glycogen is replaced over several days.

**FOCUS ON EVIDENCE**

Studies over several decades have demonstrated that if light

exercise is performed during the recovery period (*active*

*recovery*)*,* recovery from exercise occurs more rapidly than

with total rest (*passive recovery*).28,51,113,244 Faster recovery

with light exercise is probably the result of neural as well as

circulatory influences.51,244

**CLINICAL TIP**

Only if a patient is allowed adequate time to recover from

fatigue after each exercise session does muscle performance

(strength, power, or endurance) improve over time.28,113 If

a sufficient rest interval is not a recurring component of a

resistance exercise program, a patient's performance plateaus

or deteriorates. Evidence of overtraining or overwork weakness

may become apparent (see additional discussion in a

later section of this chapter). It has also been shown that

fatigued muscles are more susceptible to acute strains.190

**Age**

Muscle performance changes throughout the life span.

Whether the goal of a resistance training program is to remediate

impairments and activity limitations (functional limitations)

or enhance fitness and performance of physical

activities, an understanding of "typical" changes in muscle

performance and response to exercise during each phase of

life from early childhood through the advanced years of life

is necessary to prescribe effective, safe resistance exercises for

individuals of all ages. Key aspects of how muscle performance

changes throughout life are discussed in this section and

summarized in Box 6.3.

**Early Childhood and Preadolescence**

In absolute terms, muscle performance (specifically strength),

which in part is related to the development of muscle mass,

increases *linearly* with chronological age in both boys and

girls from birth through early and middle childhood to

puberty.191,261,290 Muscle endurance also increases linearly

during the childhood years.290 Muscle fiber number is

essentially determined prior to or shortly after birth,241

although there is speculation that fiber number may continue

to increase into early childhood.290 The rate of fiber growth

(increase in cross-sectional area) is relatively consistent from

birth to puberty. Change in fiber type distribution is relatively

complete by the age of 1, shifting from a predominance of

type II fibers to a more balanced distribution of type I and

type II fibers.290

Throughout childhood, boys have slightly greater absolute

and relative muscle mass (kilograms of muscle per kilogram

of body weight) than girls, with boys approximately 10%

stronger than girls from early childhood to puberty.191 This

difference may be associated with differences in relative muscle

mass, although social expectations, especially by midchildhood,

also may contribute to the observed difference in muscle

strength.

It is well established that an appropriately designed resistance

exercise program can improve muscle strength in children

above and beyond gains attributable to typical growth and

development. Furthermore, training-induced strength gains

in prepubescent children occur primarily as the result of

neuromuscular adaptation---that is, without a significant

increase in muscle mass.22,91 Reviews of the literature90,92 have

cited many studies that support these findings. However, there

**CHAPTER 6** Resistance Exercise for Impaired Muscle Performance
**163**

**164** Skeletal Muscle Function and Adaptation to Resistance Exercise

**BOX 6.3 Summary of Age-Related Changes in Muscle and Muscle
Performance Through the Life Span**

**Infancy, Early Childhood, and Preadolescence**

At birth, muscle accounts for about 25% of body weight.

Total number of muscle fibers is established prior to birth or

early in infancy.

Postnatal changes in distribution of type I and type II fibers in

muscle are relatively complete by the end of the first year of life.

Muscle fiber size and muscle mass increase linearly from

infancy to puberty.

Muscle strength and muscle endurance increase linearly with

chronological age in boys and girls throughout childhood until

puberty.

Muscle mass (absolute and relative) and muscle strength is

just slightly greater (approximately 10%) in boys than girls

from early childhood to puberty.

Training-induced strength gains occur equally in both sexes

during childhood *without* evidence of hypertrophy (increased

muscle mass) until puberty.

**Puberty**

Rapid acceleration in muscle fiber size and muscle mass,

especially in boys. During puberty, muscle mass increases

more than 30% per year.

Rapid increase in muscle strength in both sexes.

Marked difference in strength levels develops in boys and girls.

In boys, muscle mass and body height and weight peak before

muscle strength; in girls, strength peaks before body weight.

Relative strength gains as the result of resistance training are

comparable between the sexes, with significantly greater

muscle hypertrophy in boys.

**Young and Middle Adulthood**

Muscle mass peaks in women between 16 and 20 years of age;

muscle mass in men peaks between 18 and 25 years of age.

Decreases in muscle mass begin to occur as early as 25 years

of age.

Muscle mass constitutes approximately 40% of total body

weight during early adulthood, with men having slightly more

muscle mass than women.

Muscle continues to develop into the second decade,

especially in men.

Muscle strength and endurance reach a peak during the

second decade, earlier for women than men.

By sometime in the third decade, strength declines between

8% and 10% per decade through the fifth or sixth decade.

Strength and muscle endurance deteriorate less rapidly in

physically active versus sedentary adults.

Improvements in strength and endurance are possible with

only a modest increase in physical activity.

**Late Adulthood**

Rate of decline of muscle strength accelerates to 15% to 20%

per decade during the sixth and seventh decades and

increases to 30% per decade thereafter.

By the eighth decade, as loss of muscle mass continues;

skeletal muscle mass has decreased by 50% compared to

peak muscle mass during young adulthood.

Muscle fiber size (cross-sectional area), type I and type II fiber

numbers, and the number of alpha motoneurons all decrease.

Preferential atrophy of type II muscle fibers occurs.

Decreases in the speed of muscle contractions and peak

power occur.

Gradual but progressive decrease in endurance and maximum

oxygen uptake.

Loss of flexibility reduces the force-producing capacity of

muscle.

Minimal decline in performance of functional skills occurs

during the sixth decade.

Significant deterioration in functional abilities by the eighth

decade is associated with a decline in muscular endurance.

With a resistance training program, a significant improvement

in muscle strength, power, and endurance is possible during

late adulthood.

Evidence of the impact of resistance training on the level

of performance of functional motor skills is mixed but

promising.

is concern that children who participate in resistance training

may be at risk for injuries, such as an epiphyseal fracture or

avulsion fracture, because the musculoskeletal system is

immature.22,27,103,266

The American Academy of Pediatrics,6 the American

College of Sports Medicine (ACSM),8 and the Centers for

Disease Control and Prevention (CDC)36 support youth participation

in resistance training programs if they are designed

appropriately, initiated at a reasonable age, and carefully

supervised (Fig. 6.1). With this in mind, two important

questions need to be addressed: (1) At what point during

childhood is a resistance training program appropriate? and

\(2) What constitutes a safe training program?

There is general consensus that during the toddler, preschool,

and even the early elementary school years, free play

and organized but age-appropriate physical activities are

effective methods to promote fitness and improve muscle

performance, rather than structured resistance training

programs. The emphasis throughout most or all of the first

decade of life should be on recreation and learning motor

skills.278

There is lack of agreement, however, on when and under

what circumstances resistance training is an appropriate

form of exercise for prepubescent children. Although ageappropriate

physical activity on a regular basis has been recommended

for children for some time,6,8,36 during the past

two or three decades it has become popular for older (preadolescent)

boys and girls to participate in sport-specific training

programs (including resistance exercises) before, during, and

even after the season, in theory, to enhance athletic performance

and reduce the risk of sport-related injury. Rehabilitation

programs for prepubescent children who sustain injuries

during everyday activities also may include resistance exercises.

Consequently, an understanding of the effects of exercise in

this age group must be the basis for establishing a safe program

with realistic goals.

**FOCUS ON EVIDENCE**

In the preadolescent age group, many studies have shown that

improvements in strength and muscular endurance occur on

a relative basis similar to training-induced gains in young

adults.27,92,93,148 It is also important to point out that, although

only a few studies have looked at the effects of detraining in

children, when training ceases, strength levels gradually return

to a pre-training level, as occurs in adults.89 This suggests that

some maintenance level of training could be useful in children

as with adults.90

Although training-induced gains in strength and muscular

endurance are well-documented, there is insufficient evidence

to suggest that a structured resistance training program for

children (coupled with a general sports conditioning program)

reduces injuries or enhances sports performance.6 However,

other health-related benefits of a balanced exercise program

have been noted, including increased cardiopulmonary

fitness, decreased blood lipids levels, and improved psychological

well-being.22,27,89,148 These findings suggest that participation

in a resistance training program during the later

childhood (preadolescent) years may, indeed, be of value if

the program is performed at an appropriate level (low loads

and repetitions), incorporates sufficient rest periods, and is

closely supervised.6,22,90,266

**Adolescence**

At puberty, as hormonal levels change, there is rapid acceleration

in the development of muscle strength, especially in

boys. During this phase of development, typical strength

levels become markedly different in boys and girls, which, in

part, are caused by hormonal differences between the sexes.

Strength in adolescent boys increases about 30% per year

between ages 10 and 16, with muscle mass peaking before

muscle strength.34,191 In adolescent girls, peak strength develops

before peak weight.95 Overall, during the adolescent years,

muscle mass increases more than 5-fold in boys and approximately

3.5-fold in girls.34,191 Although most longitudinal

studies of growth stop at age 18, strength continues to develop,

particularly in males, well into the second and even into the

third decade of life.191

As with prepubescent children, resistance training during

puberty also results in significant strength gains. During

puberty, these gains average 30% to 40% above that which is

expected as the result of normal growth and maturation.90 A

balanced training program for the adolescent involved in a

sport often includes off-season and preseason aerobic conditioning

and low-intensity resistance training followed by

more vigorous, sport-specific training during the season.22

The benefits of strength training noted during puberty are

similar to those that occur in prepubescent children.89,93

**Young and Middle Adulthood**

Although data on typical strength and endurance levels during

the second through the fifth decades of life are more often

from studies of men than women, a few generalizations can

be made that seem to apply to both sexes.185 Strength reaches

a maximal level earlier in women than men, with women

reaching a peak during the second decade and in most men

by age 30. Strength then declines approximately 1% per

year,290 or 8% per decade.107 This decline in strength appears

to be minor until about age 50278 and tends to occur at a

later age or slower rate in active adults versus those who are

sedentary.110,290 The potential for improving muscle performance

with a resistance training program (Fig. 6.2 A and B) or

by participation in even moderately demanding activities

several times a week is high during this phase of life. Guidelines

for young and middle-aged adults participating in

resistance training as part of an overall fitness program have

been published by the ACSM8 and the CDC.35

**Late Adulthood**

The rate of decline in the tension-generating capacity of muscle

in most cases accelerates to approximately 15% to 20% per

**CHAPTER 6** Resistance Exercise for Impaired Muscle Performance
**165**

**FIGURE 6.1** Resistance training, if initiated during the
preadolescent

years, should be performed using body weight or light weights and

carefully supervised.

decade in men and women in their sixties and seventies, and

it increases to 30% per decade thereafter.110,185 However, the

rate of decline may be significantly less (only 0.3% decrease

per year) in elderly men and women who maintain a high

level of physical activity.118 These disparate findings and others

suggest that loss of muscle strength during the advanced

years may be due, in part, to progressively greater inactivity

and disuse.39 Loss of muscle in the lower extremity and trunk

strength and stability during late adulthood---most notably

during the seventies, eighties, and beyond---is associated with

a gradual deterioration of functional abilities and an increase

in the frequency of falling.39,130

The decline in muscle strength and endurance in the elderly

is associated with many factors in addition to progressive disuse

and inactivity. It is difficult to determine if these factors

are causes or effects of an age-related decrease in strength.

Neuromuscular factors include a decrease in muscle mass

(atrophy), decrease in the number of type I and II muscle

fibers with a corresponding increase in connective tissue in

muscle, a decrease in the cross-sectional size of muscle, selective

atrophy of type II fibers, and change in the length-tension

relationship of muscle associated with loss of flexibility,

more so than deficits in motor unit activation and firing

rate.35,107,141,239,271,278,295 The decline in the number of motor

units appears to begin after age 60.141 All of these changes have

an impact on strength and physical performance.

In addition to decreases in muscle strength, declines in

the speed of muscle contraction, muscle endurance, and the

ability to recover from muscular fatigue occur with advanced

age.141,271 The time needed to produce the same absolute and

relative levels of torque output and the time necessary to

achieve relaxation after a voluntary contraction are lengthened

in the elderly compared to younger adults.107 Consequently,

as velocity of movement declines, so does the ability

to generate muscle power during activities that require quick

responses, such as rising from a low chair or making balance

adjustments to prevent a fall. Deterioration of muscle power

with age has a stronger relationship to functional limitations

and disability than does muscle strength.229

Information on changes in muscle endurance with aging

is limited. There is some evidence to suggest that the ability

to sustain low-intensity muscular effort also declines with age,

in part because of reduced blood supply and capillary density

in muscle, decreased mitochondrial density, changes in enzymatic

activity level, and decreased glucose transport.107 As a

result, muscle fatigue may tend to occur more readily in

the elderly. In the healthy and active (community-dwelling)

elderly population, the decline in muscle endurance appears

to be minimal well into the seventies.141

During the past few decades, as the health care community

and the public have become more aware of the benefits of

resistance training during late adulthood, a greater number

of older adults are participating in fitness programs that

include resistance exercises (Fig. 6.3). ACSM and the CDC

have published guidelines for resistance training for healthy

adults over 60 to 65 years of age (see Box 6.18).8,37

**FOCUS ON EVIDENCE**

A review of the literature indicates that when healthy or

frail elderly individuals participate in a resistance training

program of appropriate duration and intensity, muscle

strength and endurance increase.\* Some of these studies have

also measured pre-training and post-training levels of functional

abilities, such as balance, stair climbing, walking speed,

and rising from a chair. The effect of strength and endurance

training on functional abilities is promising but still inconclusive,

with most but not all39 investigations demonstrating

a positive impact.3,40,48,97,145,177,227,265

The disparity of outcomes among investigations underscores

the point that resistance training has a direct impact

on muscle performance but only an indirect impact on functional

performance, a more complex variable. Studies of

elderly individuals also have shown that if resistance training

is discontinued, detraining gradually occurs; subsequently,

**166** Skeletal Muscle Function and Adaptation to Resistance Exercise

**FIGURE 6.2** Conditioning and fitness programs for active young and
middle-aged adults include resistance training with a balance of

**(A)** upper extremity and **(B)** lower extremity strengthening
exercises.

**A B**

\*39,40,47,120,145,177,202,246,263,265,298

strength and functional capabilities deteriorate close to

pre-training levels.46,177

In summary, evidence indicates that the decline in muscle

strength and functional abilities that occurs during late

adulthood can be slowed or at least partially reversed with

a resistance training program. However, as in other age

groups, if these training-induced improvements are to be

maintained, some degree of resistance training must be

continued.295

**Psychological and Cognitive Factors**

An array of psychological factors can positively or negatively

influence muscle performance and how easily, vigorously, or

cautiously a person moves. Just as injury and disease adversely

affect muscle performance, so can a person's mental status.

For example, fear of pain, injury, or re-injury, depression related

to physical illness, or impaired attention or memory as

the result of age, head injury, or the side effects of medication

can adversely affect the ability to develop or sustain sufficient

muscle tension for execution or acquisition of functional

motor tasks. In contrast, psychological factors can positively

influence physical performance.

The principles and methods employed to maximize motor

performance and learning as functions of effective patient education

are discussed in Chapter 1. These principles and

methods should be applied in a resistance training program

to develop a requisite level of muscle strength, power, and

endurance for functional activities. The following interrelated

psychological factors as well as other aspects of motor learning

may influence muscle performance and the effectiveness of a

resistance training program.

**Attention**

A patient must be able to focus on a given task (exercise) to

learn how to perform it correctly. Attention involves the

ability to process relevant data while screening out irrelevant

information from the environment and to respond to internal

cues from the body. Both are necessary when first learning

an exercise and later when carrying out an exercise program

independently. Attention to form and technique during resistance

training is necessary for patient safety and optimal

long-term training effects.

**Motivation and Feedback**

If a resistance exercise program is to be effective, a patient

must be willing to put forth and maintain sufficient effort and

adhere to an exercise program over time to improve muscle

performance for functional activities. Use of activities that are

meaningful and are perceived as having potential usefulness

or periodically modifying an exercise routine help maintain

a patient's interest in resistance training. Charting or graphing

a patient's strength gains, for example, also helps sustain

motivation. Incorporating gains in muscle performance into

functional activities as early as possible in a resistance exercise

program puts improvements in strength to practical use,

thereby making those improvements meaningful.

The importance of feedback for learning an exercise or a

motor skill is discussed in Chapter 1. In addition, feedback

can have a positive impact on a patient's motivation and subsequent

adherence to an exercise program. For example, some

computerized equipment, such as isokinetic dynamometers,

provide visual or auditory signals that let the patient know if

each muscle contraction during a particular exercise is in a

zone that causes a training effect. Documenting improvements

over time, such as the amount of weight (exercise load)

used during various exercises or changes in walking distance

or speed, also provides positive feedback to sustain a patient's

motivation in a resistance exercise program.

**Physiological Adaptations**

**to Resistance Exercise**

The use of resistance exercise in rehabilitation and conditioning

programs has a substantial impact on all systems of the

body. Resistance training is equally important for patients

with impaired muscle performance and individuals who wish

to improve or maintain their level of fitness, enhance performance,

or reduce the risk of injury. When body systems

are exposed to a greater than usual but appropriate level of

resistance in an exercise program, they initially react with a

number of *acute* physiological responses and then later

adapt---that is, body systems accommodate over time to the

newly imposed physical demands.8,9,192 Training-induced

adaptations to resistance exercise, known as *chronic* physiological

responses, that affect muscle performance are summarized

in Table 6.3 and discussed in this section. Key differences

**CHAPTER 6** Resistance Exercise for Impaired Muscle Performance
**167**

**FIGURE 6.3** Incorporating resistance training into a fitness program

has many benefits for older adults.

in adaptations from strength training versus endurance training

are noted.

Adaptations to overload create changes in muscle performance

and, in part, determine the effectiveness of a resistance

training program. The time course for these adaptations to

occur varies from one individual to another and is dependent

on a person's health status and previous level of participation

in a resistance exercise program.10

**Neural Adaptations**

It is well accepted that in a resistance training program the

initial, rapid gain in the tension-generating capacity of

skeletal muscle is attributed largely to neural responses, not

adaptive changes in muscle itself.109,183,203,235 This is reflected

by an increase in electromyographic (EMG) activity during

the first 4 to 8 weeks of training with little to no evidence of

muscle fiber hypertrophy. It is also possible that increased

neural activity is the source of additional gains in strength

late in a resistance training program even after muscle hypertrophy

has reached a plateau.168,192

Neural adaptations are attributed to motor learning and

improved coordination109,167,169,192 and include *increased*

*recruitment* in the number of motor units firing as well as

an *increased rate and synchronization* of firing.109,167,225,235

It is speculated that these changes are caused by a decrease

in the inhibitory function of the central nervous system

(CNS), decreased sensitivity of the Golgi tendon organ

(GTO), or changes at the myoneural junction of the motor

unit.109,235

**Skeletal Muscle Adaptations**

**Hypertrophy**

As noted previously, the tension-producing capacity of muscle

is directly related to the physiological cross-sectional area

of the individual muscle fibers. *Hypertrophy* is an increase in

the size (bulk) of an individual muscle fiber caused by an increase

in myofibrillar volume.206,271 After an extended period

of moderate- to high-intensity resistance training, usually by

4 to 8 weeks1,287 but possibly as early as 2 to 3 weeks with very

high-intensity resistance training,255 hypertrophy becomes an

increasingly important adaptation that accounts for strength

gains in muscle.

Although the mechanism of hypertrophy is complex

and the stimulus for growth is not clearly understood, hypertrophy

of skeletal muscle appears to be the result of an

increase in protein (actin and myosin) synthesis and a

decrease in protein degradation. Hypertrophy is also associated

with biochemical changes that stimulate uptake of

amino acids.167,192,206,271

The greatest increases in protein synthesis and, therefore,

hypertrophy are associated with high-volume, moderateresistance

exercise performed eccentrically.167,232 Furthermore,

it is the type IIB muscle fibers that appear to increase

in size most readily with resistance training.192,210

**168** Skeletal Muscle Function and Adaptation to Resistance Exercise

**TABLE 6.3** Physiological Adaptations to Resistance Exercise

**Variable Strength Training Adaptations Endurance Training
Adaptations**

Skeletal muscle structure

Neural system

Metabolic system and

enzymatic activity

Body composition

Connective tissue

Minimal or no muscle fiber hypertrophy

↑ in capillary bed density

↑ in mitochondrial density and volume

(↑ number and size)

No changes.

↑ ATP and PC storage:

↑ myoglobin storage

↑ of stored triglycerides

↑ creatine phosphokinase

↑ myokinase

No change in lean body mass; ↓ % body fat

↑ tensile strength of tendons, ligaments,

and connective tissue in muscle

↑ in bone mineralization with land-based,

weight-bearing activities

Muscle fibers hypertrophy: greatest in type

IIB fibers.

Possible hyperplasia of muscle fibers.

Fiber type composition: remodeling of type

IIB to type IIA; no change in type I to

type II distribution (i.e., no conversion)

↓ or no change in capillary bed density:

↓ in mitochondrial density and volume

Motor unit recruitment (↑ \# of motor units

firing)

↑ rate of firing (↓ twitch contraction time)

↑ synchronization of firing

↑ ATP and PC storage

↑ myoglobin storage

Triglycerides storage: change not known

↑ creatine phosphokinase

↑ myokinase

↑ lean (fat-free) body mass; ↓ % body fat

↑ tensile strength of tendons, ligaments,

and connective tissue in muscle

↑ bone mineral density; no change or

possible ↑ in bone mass

**Hyperplasia**

Although the topic has been debated for many years and

evidence of the phenomenon is sparse, there is some thought

that a portion of the increase in muscle size that occurs with

heavy resistance training is caused by *hyperplasia*, an increase

in the *number* of muscle fibers. It has been suggested that this

increase in fiber number, observed in laboratory animals,116,117

is the result of longitudinal splitting of fibers.15,139,199 It has

been postulated that fiber splitting occurs when individual

muscle fibers increase in size to a point at which they are

inefficient, then subsequently split to form two distinct

fibers.116

Critics of the concept of hyperplasia suggest that evidence

of fiber splitting actually may be caused by inappropriate

tissue preparation in the laboratory.115 The general opinion

in the literature is that hyperplasia either does not occur, or

if it does occur to a slight degree, its impact is insignificant.

183,188 In a review article published in the late 1990s, it

was the authors' opinion that if hyperplasia is a valid finding,

it probably accounts for a very small proportion (less than

5%) of the increase in muscle size that occurs with resistance

training.169

**Muscle Fiber Type Adaptation**

As previously mentioned, type II (phasic) muscle fibers preferentially

hypertrophy with heavy resistance training. In

addition, a substantial degree of plasticity exists in muscle

fibers with respect to contractile and metabolic properties.239

Transformation of type IIB to type IIA is common with endurance

training,239 as well as during the early weeks of heavy

resistance training,255 making the type II fibers more resistant

to fatigue. There is some evidence that demonstrates type I

to type II fiber type conversion in the denervated limbs of

laboratory animals,216,302 in humans with spinal cord injury,

and after an extended period of weightlessness associated with

space flight.239 However, there is little to no evidence of type

II to type I conversion under training conditions in rehabilitation

or fitness programs.192,239

**Vascular and Metabolic Adaptations**

Adaptations of the cardiovascular and respiratory systems as

the result of low-intensity, high-volume resistance training

are discussed in Chapter 7. Opposite to what occurs with

endurance training, when muscles hypertrophy with highintensity,

low-volume training, capillary bed density actually

decreases because of an increase in the number of myofilaments

per fiber.9 Athletes who participate in heavy resistance

training actually have fewer capillaries per muscle fiber than

endurance athletes and even untrained individuals.154,269

Other changes associated with metabolism, such as a decrease

in mitochondrial density, also occur with high- intensity resistance

training.9,167 This is associated with reduced oxidative

capacity of muscle.

**Adaptations of Connective Tissues**

Although the evidence is limited, it appears that the tensile

strength of tendons and ligaments as well as bone increases

with resistance training designed to improve the strength or

power of muscles.49,259,303

**Tendons, Ligaments, and Connective Tissue**

**in Muscle**

Strength improvement in tendons probably occurs at the

musculotendinous junction, whereas increased ligament

strength may occur at the ligament-bone interface. It is believed

that tendon and ligament tensile strength increases in

response to resistance training to support the adaptive

strength and size changes in muscle.303 The connective tissue

in muscle (around muscle fibers) also thickens, giving more

support to the enlarged fibers.192 Consequently, strong ligaments

and tendons may be less prone to injury. It is also

thought that noncontractile soft tissue strength may develop

more rapidly with eccentric resistance training than with

other types of resistance exercises.258,259

**Bone**

Numerous sources indicate there is a high correlation between

muscle strength and the level of physical activity across the

life span with bone mineral density.238 Consequently, physical

activities and exercises, particularly those performed in weightbearing

positions, are typically recommended to minimize

or prevent age-related bone loss.226 They are also prescribed

to reduce the risk of fractures or improve bone density when

osteopenia or osteoporosis is already present.54,238

**FOCUS ON EVIDENCE**

Although the evidence from prospective studies is limited and

mixed, resistance exercises performed with adequate intensity

and with site-specific loading through weight bearing of

the boney area to be tested has been shown to increase or

maintain bone mineral density.156,160,174,198,209 In contrast, a

number of studies in young, healthy women231 and postmenopausal

women228,245 have reported that there was no

significant increase in bone mineral density with resistance

training. However, the resistance exercises in these studies

were not combined with site-specific weight bearing. In

addition, the intensity of the weight training programs may not

have been high enough to have an impact on bone density.174,238

The time course of the exercise program also may not have

been long enough. It has been suggested that it may take as

long as 9 months to a year of exercise for detectable and

significant increases in bone mass to occur.8 In the spine,

although studies to date have not shown that resistance training

prevents spinal fractures, there is some evidence to suggest

that the strength of the back extensors closely correlates with

bone mineral density of the spine.245

Research continues to determine the most effective

forms of exercise to enhance bone density and prevent agerelated

bone loss and fractures. For additional information

on prevention and management of osteoporosis, refer to

Chapter 11.

**CHAPTER 6** Resistance Exercise for Impaired Muscle Performance
**169**

**Determinants of Resistance**

**Exercise**

Many elements (variables) determine whether a resistance

exercise program is appropriate, effective, and safe. This holds

true when resistance training is a part of a rehabilitation program

for individuals with known or potential impairments

in muscle performance or when it is incorporated into a

general conditioning program to improve the level of fitness

of healthy individuals.

Each of the interrelated elements noted in Box 6.4 and

discussed in this section should be addressed to improve one

or more aspects of muscle performance and achieve desired

functional outcomes. Appropriate *alignment* and *stabilization*

are always basic elements of any exercise designed to

improve muscle performance. A suitable *dosage* of exercise

must also be determined. In resistance training, dosage includes

*intensity, volume, frequency,* and *duration* of exercise

and *rest interval.* Each factor is a mechanism by which the

muscle can be progressively overloaded to improve muscle

performance. The *velocity* of exercise and the *mode(type)* of

exercise must also be considered. ACSM denotes the key determinants

of a resistance training program by the acronym,

FITT, which represents frequency, intensity, time, and type

of exercise.8

Consistent with the SAID principle discussed in the first

section of this chapter, these elements of resistance exercise

must be specific to the patient's desired functional goals.

Other factors, such as the underlying cause or causes of the

deficits in muscle performance, the extent of impairment, and

the patient's age, medical history, mental status, and social

situation also affect the design and implementation of a

resistance exercise program.

**Alignment and Stabilization**

Just as correct alignment and effective stabilization are basic

elements of manual muscle testing and dynamometry, they

are also crucial in resistance exercise. To strengthen a specific

muscle or muscle group effectively and avoid substitute

motions, appropriate positioning of the body and alignment

of a limb or body segment are essential. *Substitute motions* are

compensatory movement patterns caused by muscle action

of a stronger adjacent agonist or a muscle group that normally

serves as a stabilizer (fixator).158 If the principles of alignment

and stabilization for manual muscle testing137,158 are applied

whenever possible during resistance exercise, substitute motions

can usually be avoided.

**Alignment**

***Alignment and muscle action.*** Proper alignment is determined

by the direction of muscle fibers and the line of pull

of the muscle to be strengthened. The patient or a body

segment must be positioned so the direction of movement of

a limb or segment of the body replicates the action of the

muscle or muscle groups to be strengthened. For example, to

strengthen the gluteus medius, the hip must remain slightly

extended, not flexed, and the pelvis must be rotated slightly

forward as the patient abducts the lower extremity against the

applied resistance. If the hip is flexed as the leg abducts, the

adjacent tensor fasciae latae becomes the prime mover and is

strengthened.

***Alignment and gravity.*** The alignment or position of the

patient or the limb with respect to gravity also may be

important during some forms of resistance exercises, particularly

if body weight or free weights (dumbbells, barbells,

cuff weights) are the source of resistance. The patient or

limb should be positioned so the muscle being strengthened

acts against the resistance of gravity and the weight. This,

of course, is contingent on the comfort and mobility of the

patient.

Staying with the example of strengthening the gluteus

medius, if a cuff weight is placed around the lower leg, the

patient must assume the side-lying position so abduction

occurs through the full ROM against gravity and the additional

resistance of the cuff weight. If the patient rolls toward

the supine position, the resistance force is applied primarily

to the hip flexors, not the abductors.

**Stabilization**

Stabilization refers to holding down a body segment or holding

the body steady.158 To maintain appropriate alignment,

ensure the correct muscle action and movement pattern, and

avoid unwanted substitute motions during resistance exercise,

**170** Determinants of Resistance Exercise

**BOX 6.4 Determinants of a Resistance**

**Exercise Program**

*Alignment* of segments of the body during exercise

*Stabilization* of proximal or distal joints to prevent

substitution

*Intensity:* the exercise load (level of resistance)

*Volume:* the total number of repetitions and sets in an

exercise session

*Exercise order:* the sequence in which muscle groups are

exercised during an exercise session

*Frequency:* the number of exercise sessions per day or

per week

*Rest interval:* time allotted for recuperation between sets

and sessions of exercise

*Duration:* total time frame of a resistance training program

*Mode* of exercise: type of muscle contraction, position of

the patient, form (source) of resistance, arc of movement,

or the primary energy system utilized

*Velocity* of exercise

*Periodization:* variation of intensity and volume during

specific periods of resistance training

*Integration of exercises into functional activities:* use of

resistance exercises that approximate or replicate

functional demands

effective stabilization is imperative. Exercising on a stable

surface, such as a firm treatment table, helps hold the body

steady. Body weight also may provide a source of stability

during exercise, particularly in the horizontal position. It is

most common to stabilize the proximal attachment of the

muscle being strengthened, but sometimes the distal attachment

is stabilized as the muscle contracts.

Stabilization can be achieved externally or internally.

External stabilization can be applied manually by the therapist

or sometimes by the patient with equipment, such as

belts and straps, or by a firm support surface, such as the

back of a chair or the surface of a treatment table.

*Internal stabilization* is achieved by an isometric contraction

of an adjacent muscle group that does not enter into

the movement pattern but holds the body segment of the

proximal attachment of the muscle being strengthened

firmly in place. For example, when performing a bilateral

straight leg raise, the abdominals contract to stabilize the

pelvis and lumbar spine as the hip flexors raise the legs.

This form of stabilization is effective only if the fixating

muscle group is strong enough or not fatigued.

**Intensity**

The *intensity* of exercise in a resistance training program is

the amount of resistance (weight) imposed on the contracting

muscle during each repetition of an exercise. The amount of

resistance is also referred to as the *exercise load* (training

load)---that is, the extent to which the muscle is loaded or

how much weight is lifted, lowered, or held.

Remember, consistent with the overload principle,

to improve muscle performance the muscle must be loaded

to an extent greater than loads usually incurred. One

way to overload a muscle progressively is to gradually

increase the amount of resistance used in the exercise

program.8,10,103,168,169 The intensity of exercise and the

degree to which the muscle is overloaded is also dependent

on the volume, frequency, and order of exercise or the

length of rest intervals.

**Submaximal Versus Maximal Exercise Loads**

Many factors, such as the goals and expected functional

outcomes of the exercise program; the cause of deficits in

muscle performance; the extent of impairment; the stage

of healing of injured tissues; the patient's age, general

health, and fitness level; and other factors, determine

whether the exercise is carried out against submaximal or

maximal muscle loading. In general, the level of resistance

is often lower in rehabilitation programs for persons with

impairments than in conditioning programs for healthy

individuals.

Indications for submaximal loading for moderate to lowintensity

exercise versus near-maximal or maximal loading

for high-intensity exercise are summarized in Table 6.4.

**PRECAUTION:** The intensity of exercise should never be

so great as to cause pain. As the intensity of exercise increases

and a patient exerts a maximal or near-maximal effort,

cardiovascular risks increase substantially. A patient needs to

be continually reminded to incorporate rhythmic breathing

into each repetition of an exercise to minimize these risks.

**CHAPTER 6** Resistance Exercise for Impaired Muscle Performance
**171**

**TABLE 6.4** Indications for Low-Intensity Versus High-Intensity
Exercise

**Submaximal Loading Near-Maximal or Maximal Loading**

In the early stages of soft tissue healing when injured

tissues must be protected.

After prolonged immobilization when the articular cartilage

is not able to withstand large compressive forces or when

bone demineralization may have occurred, increasing the

risk of pathological fracture to evaluate the patient's

response to resistance exercise, especially after an

extended period of inactivity.

When initially learning an exercise to emphasize the

correct form.

For most children or older adults.

When the goal of exercise is to improve muscle endurance.

To warm-up and cool-down prior to and after a session of

exercise.

During slow-velocity isokinetic training to minimize

compressive forces on joints.

When the goal of exercise is to increase muscle strength

and power and possibly increase muscle size.

For otherwise healthy adults in the advanced phase of a

rehabilitation program after a musculoskeletal injury in

preparation for returning to high-demand occupational or

recreational activities.

In a conditioning program for individuals with no known

pathology.

For individuals training for competitive weight lifting or body

building.

**Initial Exercise Load (Amount of Resistance)**

**and Documentation of Training Effects**

It is always challenging to estimate how much resistance to

apply manually or how much weight a patient should use

during resistance exercises to improve muscle strength particularly

at the beginning of a strengthening program. With

manual resistance exercise, the decision is entirely subjective,

based on the therapist's judgment during exercise. In an

exercise program using mechanical resistance, the determination

can be made quantitatively.

**Repetition Maximum**

One method of measuring the effectiveness of a resistance

exercise program and calculating an appropriate exercise load

for training is to determine a repetition maximum. This term

was first reported decades ago by DeLorme in his investigations

of an approach to resistance training called progressive

resistive exercise (PRE).64,65 A *repetition maximum* (RM) is

defined as the greatest amount of weight (load) a muscle can

move through the full, available ROM with control a specific

number of times before fatiguing.

***Use of a repetition maximum.*** There are two main reasons

for determining a repetition maximum: (1) to document a

baseline measurement of the dynamic strength of a muscle

or muscle group against which exercise-induced improvements

in strength can be compared; and (2) to identify an

initial exercise load (amount of weight) to be used during

exercise for a specified number of repetitions. DeLorme reported

use of a 1-RM (the greatest amount of weight a subject

can move through the available ROM just one time) as the

baseline measurement of a subject's maximum effort but used

a multiple RM, specifically a 10-RM, (the amount of weight

that could be lifted and lowered 10 times through the ROM)

during training.65

Despite criticism that establishing a 1-RM involves some

trial and error, it is a frequently used method for measuring

muscle strength in research studies and has been shown to be

a safe and reliable measurement tool with healthy young

adults and athletes103,169 as well as active older adults prior to

beginning conditioning programs.202,265,276

**PRECAUTION:** Use of a 1-RM as a baseline measurement of

dynamic strength is inappropriate for some patient populations

because it requires one maximum effort. It is not safe for

patients, for example, with joint impairments, patients who are

recovering from or who are at risk for soft tissue injury, or

patients with known or at risk for osteoporosis or cardiovascular

pathology.

**CLINICAL TIP**

To avoid the trial and error associated with establishing a

1-RM or to eliminate the need for an at-risk patient to exert

a single, maximum effort, formulas have been developed

and tables have been published18,140 that enable a therapist to

calculate a 1-RM for each muscle group to be strengthened

based on the patient performing a greater number of repetitions

against a reduced load.

Another practical, time-saving way to establish a baseline

RM as an index for assessing dynamic strength for a particular

muscle group is for a therapist to select a specific amount of

resistance (weight) and document how many repetitions can

be completed through the full range before the muscle begins

to fatigue. If six repetitions, for example, were completed, the

baseline resistance would be based on a 6-RM. Remember, a

sign of fatigue is the inability to complete the full, available

ROM against the applied resistance.

**Alternative Methods of Determining Baseline**

**Strength or an Initial Exercise Load**

Cable tensiometry192 and isokinetic or handheld dynamometry57

are alternatives to a repetition maximum for establishing

a baseline measurement of dynamic or static strength. A

percentage of body weight also has been proposed to estimate

how much resistance (load) should be used in a strength

training program.236 Some examples for several exercises are

noted in Box 6.5. The percentages indicated are meant as guidelines

for the advanced stage of rehabilitation and are based

on 10 repetitions of each exercise at the beginning of an exercise

program. Percentages vary for different muscle groups.

When a maximum effort is inappropriate, the level of

perceived loading, as measured by the Borg CR 10 Scale, has

been shown to be a useful tool in estimating an appropriate

level of resistance and sufficient exercise intensity for muscle

strengthening.13

**Training Zone**

After establishing the baseline RM, the amount of resistance

(exercise load) to be used at the initiation of resistance training

often is calculated as a *percentage* of a 1-RM for a particular

muscle group. At the beginning of an exercise program

the percentage necessary to achieve training-induced adaptations

in strength is low (30% to 40%) for sedentary, untrained

individuals or very high (\>80%) for those already highly

trained. For healthy but untrained adults, a typical training

zone usually falls between 40% and 70% of the baseline

RM.8,10,14 The lower percentage of this range is safer at the

beginning of a program to enable an individual to focus on

learning correct exercise form and technique before progressing

the exercise load to 60% to 70%.

**172** Determinants of Resistance Exercise

**BOX 6.5 Percentage of Body Weight as an**

**Initial Exercise Load for Selected**

**Exercises**

Universal bench press: 30% body weight

Universal leg extension: 20% body weight

Universal leg curl: 10% to 15% body weight

Universal leg press: 50% body weight

Exercising at a low to moderate percentage of the established

RM is recommended for children and the elderly.8,10

For patients with significant deficits in muscle strength or to

train for muscular endurance, using a low load---possibly at

the 30% to 50% level---is safe yet challenging.

**Volume**

In resistance training the *volume* of exercise is the summation

of the total number of repetitions and sets of a particular

exercise during a single exercise session times the intensity of

the exercise.8,10,168 The same combination of repetitions and

sets is not and should not be used for all muscle groups.

There is an inverse relationship between the sets and repetitions

of an exercise and the intensity of the resistance. The

higher the intensity (load), the lower the number of repetitions

and sets possible. Conversely, the lower the load, the

greater the number of repetitions and sets possible. Therefore,

the exercise load directly dictates how many repetitions and

sets are possible.

***Repetitions.*** The number of repetitions in a dynamic exercise

program refers to the number of times a particular movement

is repeated. More specifically, it is the number of muscle

contractions performed to move the limb through a series

of continuous and complete excursions against a specific

exercise load.

If the RM designation is used, the number of repetitions

at a specific exercise load is reflected in the designation. For

example, 10 repetitions at a particular exercise load is a 10-RM.

If a 1-RM has been established as a baseline level of dynamic

strength, a percentage of the 1-RM used as the exercise load

influences the number of repetitions a patient is able to perform

before fatiguing. The "average," untrained adult, when

exercising with a load that is equivalent to 75% of the 1-RM,

is able to complete approximately 10 repetitions before

needing to rest.18,192 At 60% intensity about 15 repetitions are

possible, and at 90% intensity only 4 or 5 repetitions are

usually possible.

For practical reasons, after a beginning exercise load is

selected, the target number of repetitions performed for each

exercise before a brief rest is often within a range rather than

an exact number of repetitions. For example, a patient might

be able to complete between 8 and 10 repetitions against a

specified load before resting. This is sometimes referred to

as a *RM zone,*192 it gives the patient a goal but builds in some

flexibility.

The number of repetitions selected depends on the patient's

status and whether the goal of the exercise is to improve

muscle strength or endurance. No optimal number for

strength training or endurance training has been identified.

Training effects (greater strength) have been reported employing

a 2- to 3-RM to a 15-RM.18,170

***Sets.*** A predetermined number of consecutive repetitions

grouped together is known as a *set* or *bout* of exercise*.* After

each set of a specified number of repetitions, there is a brief

interval of rest. For example, during a single exercise session

to strengthen a particular muscle group, a patient might be

directed to lift an exercise load 8 to 10 times, rest, and then

lift the load another 8 to 10 times. That would be two sets of

an 8- to 10-RM.

As with repetitions, there is no optimal number of sets per

exercise session, but 2 to 4 sets is a common recommendation

for adults.8 As few as one set and as many as six sets, however,

have yielded positive training effects.10,168 Single-set exercises

at low intensities are most common in the very early phases

of a resistance exercise program or in a maintenance program.

Multiple-set exercises are used to progress the program and

have been shown to be superior to single-set regimens in

advanced training.170

**Training to Improve Strength or Endurance:**

**Impact of Exercise Load and Repetitions**

Overall, because many variations of intensity and volume

cause positive training-induced adaptations in muscle performance,

there is a substantial amount of latitude for selecting

an exercise load/repetition and set scheme for each exercise.

The question becomes: Is the goal to improve strength, power,

or muscular endurance?

**To Improve Muscle Strength**

In DeLorme's early studies,64,65 three sets of a 10-RM performed

for 10 repetitions over the training period led to gains in

strength. Current recommendations for strength training vary

somewhat. One resource14 suggests that a threshold of 40% to

60% of maximum effort is necessary for adaptive strength gains

to occur in a healthy but untrained individual. However, other

resources recommend using a moderate exercise load (60% to

80% of a 1-RM) that causes fatigue after 8 to 12 repetitions

for 2 or 3 sets.8,168 When fatigue no longer occurs after the

target number of repetitions has been completed, the level of

resistance is increased to overload the muscle once again.

**To Improve Muscle Endurance**

Training to improve muscle (local) endurance involves performing

many repetitions of an exercise against a submaximal

load.9,168,260 For example, as many as three to five sets of 40

to 50 repetitions against a low amount of weight or a light

grade of elastic resistance might be used. When increasing the

number of repetitions or sets becomes inefficient, the load

can be increased slightly.

Endurance training also can be accomplished by maintaining

an isometric muscle contraction for incrementally longer

periods of time. Because endurance training is performed

against very low levels of resistance, it can and should be

initiated very early in a rehabilitation program without risk

of injury to healing tissues.

**CLINICAL TIP**

When injured muscles are immobilized, type I (slow twitch)

muscle fibers atrophy at a faster rate than type II (fast twitch)

fibers.206 There is also a slow to fast muscle fiber type

**CHAPTER 6** Resistance Exercise for Impaired Muscle Performance
**173**

conversion with disuse. These changes give rise to a much

faster rate of atrophy of antigravity muscles compared with

their antagonists,183 underscoring the need for early initiation

of endurance training following injury or surgery.

**Exercise Order**

The sequence in which exercises are performed during an

exercise session has an impact on muscle fatigue and adaptive

training effects. When several muscle groups are exercised in

a single session, as is the case in most rehabilitation or conditioning

programs, large muscle groups should be exercised

before small muscle groups, and multi-joint exercises should

be performed before single-joint exercises.10,103,167,168 In

addition, after an appropriate warm-up, higher intensity exercises

should be performed before lower intensity exercises.10

**Frequency**

*Frequency* in a resistance exercise program refers to the number

of exercise sessions per day or per week.8,10 Frequency also

may refer to the number of times per week specific muscle

groups are exercised or certain exercises are performed.8,168

As with other aspects of dosage, frequency is dependent on

other determinants, such as intensity and volume as well as

the patient's goals, general health status, previous participation

in a resistance exercise program, and response to training.

The greater the intensity and volume of exercise, the more

time is needed between exercise sessions to recover from the

temporarily fatiguing effects of exercise. A common cause of

a decline in performance from overtraining (see discussion

later in the chapter) is excessive frequency, inadequate rest

intervals, and progressive fatigue.

Some forms of exercise should be performed less frequently

than others because they require greater recovery

time. It has been known for some time that high-intensity

*eccentric* exercise, for example, is associated with greater

microtrauma to soft tissues and a higher incidence of

delayed-onset muscle soreness than concentric exercise.16,106,212

Therefore, rest intervals between exercise sessions are longer

and the frequency of exercise is less than with other forms

of exercise.

Although an optimal frequency per week has not been

determined, a few generalizations can be made. Initially in an

exercise program, short sessions of exercises sometimes can

be performed on a daily basis several times per day as long as

the intensity of exercise and number of repetitions are low.

This frequency often is indicated for early postsurgical

patients when the operated limb is immobilized and the extent

of exercise is limited to nonresisted isometric (setting)

exercises to minimize the risk of muscle atrophy. As the intensity

and volume of exercise increases, a frequency of

2 to 3 times per week, every other day, or up to five exercise

sessions per week is common.8,10,103,167 A rest interval of

48 hours for training major muscle groups can be achieved

by exercising the upper extremities one day and the lower

extremities during the next exercise session.

Frequency is again reduced for a maintenance program,

usually to two times per week. With prepubescent children

and the very elderly, frequency typically is limited to no more

than 2 to 3 sessions per week.8,10,36,37 Highly trained athletes

involved in body building, power lifting, and weight lifting,

who know their own response to exercise, often train at a

high-intensity and volume up to 6 days per week.10,168,170

**Duration**

Exercise *duration* is the total number of weeks or months

during which a resistance exercise program is carried out.

Depending on the cause of impaired muscle performance,

some patients require only a month or two of training to

return to the desired level of function or activity, whereas

others need to continue the exercise program for a lifetime to

maintain optimal function.

As noted earlier in the chapter, strength gains observed early

in a resistance training program (after 2 to 3 weeks) primarily

are the result of neural adaptation. For significant changes to

occur in muscle, such as hypertrophy or increased vascularization,

at least 6 to 12 weeks of resistance training is required.1,8,192

**Rest Interval (Recovery Period)**

***Purpose of rest intervals.*** Rest is a critical element of a
resistance

training program and is necessary to allow time for

the body to recuperate from the acute effects of exercise associated

with muscle fatigue or to offset adverse responses,

such as exercise-induced, delayed-onset muscle soreness. Only

with an appropriate balance of progressive loading and adequate

rest intervals can muscle performance improve. Therefore,

rest between sets of exercise and between exercise

sessions must be addressed.

***Integration of rest into exercise.*** Rest intervals for each

exercising muscle group are dependent on the intensity and

volume of exercise. In general, the higher the intensity of

exercise the longer the rest interval. For moderate-intensity

resistance training, a 2- to 3-minute rest period after each set

is recommended. A shorter rest interval is adequate after

low-intensity exercise. Longer rest intervals (\>3 minutes) are

appropriate with high-intensity resistance training, particularly

when exercising large, multi-joint muscles, such as the hamstrings,

which tend to fatigue rapidly.8,10 While the muscle

group that was just exercised is resting, resistance exercises

can be performed by another muscle group in the same extremity

or by the same muscle group in the opposite extremity.

Patients with pathological conditions that make them

more susceptible to fatigue, as well as children and the elderly,

should rest at least 3 minutes between sets by performing a

nonresisted exercise, such as low-intensity cycling, or performing

the same exercise with the opposite extremity. Remember,

active recovery is more efficient than passive recovery for

neutralizing the effects of muscle fatigue.

**174** Determinants of Resistance Exercise

Rest between exercise sessions must also be considered.

When strength training is initiated at moderate intensities

(typically in the intermediate phase of a rehabilitation program

after soft tissue injury), a 48-hour rest interval between

exercise sessions (that is, training every other day) allows the

patient adequate time for recovery.

**Mode of Exercise**

The *mode* of exercise in a resistance exercise program refers

to the form of exercise, the type of muscle contraction that

occurs, and the manner in which the exercise is carried out.

For example, a patient may perform an exercise dynamically

or statically or in a weight-bearing or nonweight-bearing

position. Mode of exercise also encompasses the form of

resistance---that is, how the exercise load is applied. Resistance

can be applied manually or mechanically.

As with other determinants of resistance training, the

modes of exercise selected are based on a multitude of factors

already highlighted throughout this section. A brief overview

of the various modes of exercise is presented in this section.

An in-depth explanation and analysis of each of these types

of exercise can be found in the next section of this chapter

and in Chapter 7.

**Type of Muscle Contraction**

Figure 6.4 depicts the types of muscle contraction that may

be performed in a resistance exercise program and their relationships

to each other and to muscle performance.182,210,248

Isometric (static) or dynamic muscle contractions are two

broad categories of exercise.

Dynamic resistance exercises can be performed using *concentric*

(shortening) or *eccentric* (lengthening) contractions,

or both.

When the velocity of limb movement is held consistent by

a rate-controlling device, the term *isokinetic* contraction is

sometimes used.248 An alternative perspective is that this is

simply a dynamic (shortening or lengthening) contraction

that occurs under controlled conditions.182

**Position for Exercise: Weight-Bearing**

**or Nonweight-Bearing**

The patient's body position or the position of a limb in

nonweight-bearing or weight-bearing positions also alters

the mode of exercise. When a nonweight-bearing position is

assumed and the distal segment (foot or hand) moves freely

during exercise, the term open-chain exercise (or a variation

of this term) is often used. When a weight-bearing position

is assumed and the body moves over a fixed distal segment,

the term closed-chain exercise is commonly used.182,210,248

Concepts and issues associated with the use of this terminology

are addressed later in this chapter.

**Forms of Resistance**

*Manual* resistance and *mechanical* resistance are the two

broad methods by which resistance can be applied.

A *constant* or *variable* load can be imposed using mechanical

resistance (e.g., free weights or weight machines).

*Accommodating* resistance138 can be implemented by use

of an isokinetic dynamometer that controls the velocity of

active movement during exercise.

*Body weight* or partial body weight is also a source of

resistance if the exercise occurs in an antigravity position.

Although an exercise performed against only the resistance

of the weight of a body segment (and no additional external

resistance) is defined as an active rather than an activeresistive

exercise, a substantial amount of resistance from

the weight of the body can be imposed on contracting

muscles by altering a patient's position. For example, progressive

loads can be placed on upper extremity musculature

during push-ups by starting with wall push-ups while

standing, progressing to push-ups while leaning against a

countertop, push-ups in a horizontal position (Fig. 6.5),

and finally push-ups from a head-down position over a

large exercise ball.

**CHAPTER 6** Resistance Exercise for Impaired Muscle Performance
**175**

**FIGURE 6.4** Types of muscle contractions: their relationships to

muscle performance and their tension-generating capacities.

**FIGURE 6.5** Body weight serves as the source of resistance during

a push-up.

**Energy Systems**

Modes of exercise also can be classified by the energy systems

used during the exercise. Anaerobic exercise involves highintensity

(near-maximal) exercise carried out for a very few

number of repetitions because muscles rapidly fatigue.

Strengthening exercises fall into this category. Aerobic exercise

is associated with low-intensity, repetitive exercise of large

muscle groups performed over an extended period of time.

This mode of exercise primarily increases muscular and cardiopulmonary

endurance (refer to Chapter 7 for an in-depth

explanation).

**Range of Movement: Short-Arc or Full-Arc**

**Exercise**

Resistance through the full, available range of movement

(full-arc exercise) is necessary to develop strength through the

ROM. Sometimes resistance exercises are executed through

only a portion of the available range. This is known as shortarc

exercise. This form of exercise is used to avoid a painful

arc of motion or a portion of the range in which the joint is

unstable or to protect healing tissues after injury or surgery.

**Mode of Exercise and Application to Function**

Mode-specific training is essential if a resistance training

program is to have a positive impact on function. When tissue

healing allows, the type of muscle contractions performed or

the position in which an exercise is carried out should mimic

the desired functional activity as closely as possible.205

**Velocity of Exercise**

The velocity at which a muscle contracts significantly affects

the tension that the muscle produces and subsequently affects

muscular strength and power.217 The velocity of exercise is

frequently manipulated in a resistance training program to

prepare the patient for a variety of functional activities that

occur across a wide spectrum of slow to fast velocities.

**Force-Velocity Relationship**

The force-velocity relationship is different during concentric

and eccentric muscle contractions, as depicted in Figure 6.6.

**Concentric Muscle Contraction**

During a maximum effort concentric muscle contraction, as

the velocity of muscle shortening increases, the force the muscle

can generate *decreases.* EMG activity and torque decrease

as a muscle shortens at faster contractile velocities, possibly

because the muscle may not have sufficient time to develop

peak tension.53,182,210,248,294

**Eccentric Muscle Contraction**

Findings are less consistent for eccentric than concentric muscle

actions. During a maximum effort eccentric contraction,

as the velocity of active muscle lengthening increases, force

production in the muscle initially *increases* to a point but then

*quickly levels off.*38,63,182,210,248 The initial increase in force

production may be a protective response of the muscle when

it is first overloaded. It is thought that this increase may be

important for shock absorption or rapid deceleration of a

limb during quick changes of direction.78,248 The rise in

tension also may be caused by stretch of the noncontractile

tissue in muscle.63 In contrast, other research indicates that

eccentric force production is essentially unaffected by velocity

and remains constant at slow and fast velocities.53,121

**Application to Resistance Training**

A range of slow to fast exercise velocities has a place in an

exercise program. Resistance training with free weights is

safe and effective only at slow to medium velocities of limb

movement so the patient can maintain control of the moving

weight. Because many functional activities involve reasonably

fast velocities of limb movement, training at only slow

velocities is inadequate. The development of the isokinetic

dynamometer during the late 1960s138,200 gave clinicians a tool

to implement resistance training at fast as well as slow velocities.

In recent years, some variable resistance exercise units

(pneumatic and hydraulic) and elastic resistance products

also have afforded additional options for safely training at fast

velocities.

*Velocity-specific training* is fundamental to a successful

rehabilitation program. Results of numerous studies since the

1970s have shown that training-induced strength gains in a

resistance exercise program primarily occur at the training

velocities,24,80,149 with limited transfer of training (physiological

overflow) above and below the training velocities.143,273

Accordingly, training velocities for resistance exercises should

be geared to match or approach the demands of the desired

functional activities.57,149

Isokinetic training, using *velocity spectrum rehabilitation*

regimens, and *plyometric training,* also known as *stretchshortening*

*drills*, often emphasize high-speed training. These

approaches to exercise are discussed later in this chapter and

in Chapter 23, respectively.

**FIGURE 6.6** Force