Periodization Concepts for the Orthopedic Patient
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Transcript Periodization Concepts for the Orthopedic Patient
Understand what a periodized program is
To be able to manipulate the training variables
to achieve the desired muscular conditioning
effect (ex: endurance, strength, power, etc)
Aware of the adaptations that occur when
performing a strength training program
Distinguish the differences between the
spectrum of strength / power and mm
endurance
How to progress a resistance training program
based on client goals and previous training
status
Strength / fitness:
Has different meaning
for different people
depending on:
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Age
ADL’s and IADL’s
Occupation
Severity and type of injury
Healing capacity
Force: mass x acceleration
Strength is defined as the maximal amount of
force that a muscle or muscle group can
generate at a specific velocity
Work: force x distance
Power: strength x speed (work/time)
What is periodization?
Periodization is a method of planning periods or
cycles in which training specificity, intensity, and
volume changes within an overall training
program (Baechle and Earle 2000)
Manipulation of key strength training variables
that includes number of sets, reps, intensity,
repetition speed, rest periods, frequency or order
of exercises
For intermediate to advanced training, it is
recommended that individuals use a wider
loading range, from 1–12 RM in a periodized
fashion…
For loading, it is recommended that loads
corresponding to 1–12 RM be used in
periodized fashion…
Why periodize your
training programs?
Prevent overtraining
Decrease the onset of
staleness
Promote the development
of specific physical
performance parameters
Allows for “peaking” of key
performance variables that
are specific to an
individuals function
Why should a physical therapist understand
the concepts of periodization
Three sets of 10 will only get you so far!!
You must have an understanding of what the
goals of exercise are for your patients based on
the type of tissue involved, the stage of healing
and the co-morbid conditions that your patients
may have that influence their ability to train
successfully
Physiological basis for periodization
Based on the concepts of:
▪ Endocrinology
▪ Biomechanics
▪ Neurology
▪ Muscle physiology
▪ Metabolism
Types of Muscle Fibers:
Fast & Slow Twitch Fibers:
Not really just two types but a continuum between the
two.
Both are present in varying mixture in most muscles.
Classically divided into:
Type I
Type IIA
Type IIB
Types of Muscle
Fibers
Type I: Characteristics
Slow acting myosin isoform
Contract more slowly with less
force
Rely primarily on oxidative
metabolism
Many mitochondria
Myoglobin
Highly vascularized
Contain little glycogen
Small diameter
Resistant to fatigue
Type IIA:
Characteristics
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Fast acting myosin isoform
Contract rapidly with greater
force
Have high oxidative capacity
Highly vascularized
Many mitochondria
Have myoglobin
Intermediate amounts of
glycogen and anaerobic
capacity
Intermediate size
Not very common in most
people : Class switching
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Type IIB:
Characteristics
Fast acting myosin isoform
Contract rapidly with
greater force
Rely on anaerobic
metabolism
Few mitochondria
Less well vascularized
Lack myoglobin
High glycogen content
Large diameter
IIb IIab IIa IIac IIc
Strength training
converts the IIb mm
fibers to the more
oxidative IIa mm fiber
type by as much as
93%
Muscle Energetics:
Energy (ATP) Requirements for Muscular Contraction
Movement of myosin head chain:
Requires ATP hydrolysis for each stroke; majority of energy
requirements are here
Mobilization of Calcium stores:
Calcium must be pumped back into the SR at the end of each
contractile pulse. Calcium pumps on SR require ATP.
Reestablishment of membrane potential:
Contractile stimulation requires an action potential, so the
Na/K pump must be used which requires ATP.
Hydrolysis of ATP stores:
allows for ~1-2 seconds sustained contraction
Phosphocreatine: High energy phosphate to quickly
rephosphorylate ADP.
5-8 seconds sustained contraction
Glycogen and glycolysis: Muscular store of glycogen
undergoes glycolytic cycle to yield ATP, lactic acid and
2 molecules of pyruvate. Glycolysis also yields such
molecules as NADH and FADH2 to be used to
generate ATP or used in later reactions such as the
Krebs cycle. Rapid, does not require oxygen.
One minute sustained contraction
Muscle
Energetics
Oxidative metabolism: In the
mitochondria. Slow, but
capable of supplying a large
amount of energy.. Electrons
are transported from NADH,
FADH2 molecules down a
transport chain to the terminal
electron receptor O2. The end
product is a large amount of
ATP (larger than any other
metabolic process) and H2O
> Three minutes
sustained contraction
Hans Selye: Canadian
Endocrinologist
described the
physiological basis of
why periodization is
effective based on
three stages General
Adaptation Syndrome:
Periodization programs are divided into smaller
cycles of training with each cycle of training devoted
to a particular performance variable
Microcycle: smallest period of time in the model usually
one week long
Mesocycle: intermediate period in the training cycle that
consists of multiple microcycles usually from 3 weeks to 12
weeks (6-8 weeks common)
Macrocycle: long term program that last for several
months to a year. This cycle represents the entire training
cycle towards the overall goal
Periodization may minimize the various
forms of neuromuscular fatigue
Central: fatigue occurs proximal to the motor
units at the brain and / or spinal level
▪ Occurs due to prolonged duration exercises, with
decreased intensity and high volume
▪ Need CNS activation to activate the motor units
Peripheral fatigue:
Present at the motor
neuron, NMJ or mm
fibers
Occurs with more high
intensity, short duration
activities
Glycolytic metabolism
produces fatigue due to:
▪ Increase metabolites such
as lactate, H+, AMP,
phosphate
▪ Decrease substrates such
as creatine, ATP and
glycogen
Because of the varying nature of intensity
and volume, periodization allows for reduced
tendency towards fatigue by both
mechanisms
Allows for preservation of anabolic
stimulating hormones such as testosterone
while maintaining cortisol levels
Utilization of the SAID principle to allow for
specific training of mm fibers towards their
use for functional activities
Supercompensation refers
to the desired, beneficial
training effect that occurs
in direct response to the
applied training stress, and
following a recovery period
Supercompensation is the
return of the performance
level from a point of
reduced capacity that
follows a training episode,
beyond the pre-training
level and to a new, higher
performance baseline
Positive Adaptation
Negative Adaptation
Figure 1 - note that the training effect brings the performance capacity
back to a higher level
Figure 2 - note the inadequate recovery stage and its’ effect on
adaptation
Linear: progressive systematic decrease in
volume while increasing intensity between
each mesocycle specific time intervals to
focus on a particular physical attribute
Undulating / non linear: the volume and
intensity vary within each micro or
mesocycle. To be discussed later
Stages of periodization
Preparation
▪ Muscle endurance
▪ Hypertrophy
Transition period 1
▪ Basic Strength
▪ Power
Competition (Peaking period)
Transition period 2 (Active Rest)
Preparation Stage:
Muscle endurance:
▪ 2 – 3 sets of 20 – 25 reps, rest periods 30 – 60 seconds,
frequency 2 – 3 days per week
Hypertrophy:
▪ increased volume, (3-6 sets of 10-20 reps) per muscle group,
rest periods 60-90 seconds, frequency 3-4 days per week,
50% to 75% 1RM
Muscle fiber conversion of type IIB to type IIAB / IIA
Due to increased / stable concentrations of
testosterone, growth hormone, IGF to allow for mm
fiber hypertrophy
Increased Type I fiber recruitment
Increased capillary density
Increased utilization of Free Fatty Acids
Increased skeletal mm mitochondria
Reduced capacity for Type II fiber recruitment
Strength gains are due to combination of
Type I fiber hypertrophy and increased neural
recruitment
Increased Type II A activation
Conversion shift from Type IIB to
Type II A
Increased reliance on glycolytic
metabolism
Increased lactic acid production
Improved buffering of lactic acid
via production of lactate
Increase myofilament
production
Increase satellite cell
proliferation / mitosis
Strength gains are due to
increased CSA
Takes 8 – 12 weeks to occur
Preparatory stage:
Technique is not emphasized due to the high
volume of training
Goal is to build a base through increased mm /
strength endurance
Must be cautious to avoid overtraining with
increased cortisol production
Transition Period 1 :
Basic Strength: volume decreases from the hypertrophy
phase, intensity increases (3-5 sets of 4-6 reps at 80-90% 1
RM), frequency is 3-5 days per week, rest periods are 2-3
minutes
Muscle fiber emphasis are IIB fibers
Anaerobic glycolysis to creatine phosphokinase
metabolism
Primary response to training is enhanced neuromuscular
efficiency
Strength training can have a profound effect on
the hormonal, nervous, and immune systems
Hormonal adaptations
What type of strength program increases
Testosterone?
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Large mm group exercises
Heavy loads > 85% 1RM
Moderate to high volume: multiple sets and / or exercises
Short rest 30 – 60 seconds
What is Cortisol?:
stress hormone produced from the adrenal
cortex assists in remodeling of connective tissue
acute exercise that involved high volume, large
mm groups increased cortisol production
excessive production can result in mm catabolism,
and adverse immune responses
What kind of training program increases Growth
Hormone?:
high volume (10RM) for multiple sets (3) with short
rest periods (1 minute) that promotes mm
soreness (lactic acid)
Closed chain
movements done first:
Compound Strength
Exercises:
Neuromuscular / balance
Bench press
Power
Military press
Strength exercises
Rows
Open chain exercises
Lat pulldown
Endurance activities
Squat
Lunges
Deadlift
Increased recruitment
of Type IIB muscle
fibers
Improved mm
recruitment via
myotatic stretch reflex
Improved mm
recruitment via length
– tension relationship
Motor learning effects
Power exercises
Powerclean:
http://media.crossfit.com/cf-video/cfj-nov-05/hangpower-clean.wmv
Push press:
http://media.crossfit.com/cf-video/SPPPPJ155.wmv
Snatch:
http://media.crossfit.com/cf-video/cfj-nov-05/powersnatch.wmv
Transition Period:
Volume is decreased dramatically while intensity
increases
Technique and functional development is emphasized
Power and explosive compound movements are the
basis of this stage
Variables: 3-5 sets, 2-5 reps, 3-5 days/week, rest
periods 3 minutes
▪ 85-95% of 1RM (strength)
▪ 80-90% 1 RM (power) 1 – 2 reps (single events)
▪ 75-85% 1 RM (power) 3 – 5 reps (multiple events)
Transition Period:
Creatine phosphokinase
metabolism is primary
Goal is to increase
neuromuscular
components of strength
and power
▪ Increase recruitment of
larger motor units
▪ Increase motor unit firing
▪ Increase motor unit
summation
Transition Period:
Modifications for the orthopedic patient
For power development, safer to use lighter loads
with emphasis on speed of the contraction for the
development of power (~50% of 1RM) for 12-15
reps
Competition / Peaking Phase
Emphasis is on preparing for the event
Maximizing technique
Volume is low to prevent injury and fatigue
Variables are: 1-3 sets of 1-3 reps, 90-95% of 1RM,
1-5 days per week, rest periods 3-5 minutes
Done for usually one week to prevent fatigue,
overtraining and injury
Transition Period 2 (Active Rest)
Variables are 80-85% of 1RM, 2-3 sets of 6-8 reps,
2 days per week
Client pursues other fitness interests
Cross training (cycling, swimming, rowing, inline skating, etc)
This period is continued until approximately 3 – 4
months before the start of the next season or
event, then cycles repeat
FREQUENCY INTENSITY
POWER
1-2 week
85-95%
STRENGTH
3-4 week
75-85%
HYPERTROPHY 4-6 week
ENDURANCE
5-7 week
VOLUME
REST
1-4 reps
4-6min
1-2 sets
4-8 reps
2-3min
3-4 sets
60-75%
8-12
reps
4-6 sets
30-90s
<60%
12-15
reps
5-7 sets
<30s
Depends on the
training intensity /
volume
Previous exercise
status of the patient
Other physical
demands:
Job
Sport
Recreational pursuits
Beginner: (< 2 months of strength training): 2
times per week
Intermediate: (2 to 6 months): 3 – 4 times per
week
Advanced: (> 1 year): 4 - 6 times per week
Candow, D.G., and D.G. Burke.
Effect of short-term equal-volume resistance training with
different workout frequency on muscle mass and strength
in untrained men and women. J. Strength Cond. Res. 21(1)
RCT of 29 untrained volunteers (27–58 years; 23 W, 6 M )
group 1: 2X /wk @ 3 sets of 10 RM for 9 ex
group 2: 3X/Wk @ 2 sets of 10 RM for 9 ex
Outcome measures:
lean mass whole body DEXA
strength (1 rep max squat and bench press)
Both groups increased lean tissue mass (2.2%), squat
strength (28%), and bench press strength (22–30%) with
training (p 0.05), with no other differences.
Classic strength/power periodized training superior
for increasing:
maximal strength (e.g., 1 RM squat)
cycling power
motor performance
jumping ability.
Short term training has shown similar performance
improvements between periodized and multiple-set
nonperiodized models
Periodic variation in training variables is necessary for
long term resistance training.
ACSM Position Stand : Progression Models in
Resistance Training for Healthy Adults - 2002
Vary the intensity and volume within the
microcycle:
Daily Undulating Periodization
Vary volume and intensity each workout day
Example:
▪ Monday: Heavy: 85-90% 1RM
▪ Wednesday: Medium: 70-75% 1RM
▪ Friday: Light: 60-65% 1RM
Weekly Undulating Periodization
Vary volume and intensity each workout week
Example:
▪ Week 1: Heavy: 85-90% 1RM
▪ Week 2: Medium: 70-75% 1RM
▪ Week 3: Light: 60-65% 1RM
Patient / Task
% of maximum
power to
complete
Time to complete the
task
Energy System
Used
63 y/o sedentary
female with hx of
diabetes who has a
BMI of 40 who has
difficulty with sit to
stand
95%
7 seconds
Phosphagen
37 y/o fireman with 80%
a one year hx of a
quadricep tendon
repair c/o weakness
in the quads after
climbing 3 flights of
stairs
25 seconds
????
16 y/o male with
BMI of 38, 40% BF
desires a program
???
???
???
Patient / Task
% of maximum
Time to complete
power to complete the task
Energy System
Used
14 year old female 70%
800m runner c/o
right hip abductor
weakness with a
3month hx of left
LBP and changes in
her running gait at
the last 100m of
the race
2min and 20 sec
???
50 year old male
long distance
cyclist with c/o
muscular fatigue in
his lumbar
paraspinals while
15 minutes
???
25%
Thank You!