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HEMODYNAMIC AND LACTIC ACID RESPONSES TO PROPRIOCEPTIVE NEUROMUSCULAR
FACILITATION EXERCISE
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1Baskent University Department of Physical Therapy and Rehabilitation,
Ankara, Turkey.
2Baskent University Department of Sport Sciences, Ankara, Turkey
3Baskent University Vocational School of Health Sciences, Ankara,
Turkey.
| Received |
|
05 January 2006 |
| Accepted |
|
25
May 2006 |
| Published |
|
01
September 2006 |
©
Journal of Sports Science and Medicine (2006) 5, 375 - 380
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| ABSTRACT |
| The
hemodynamic and metabolic responses to proprioceptive neuromuscular
facilitation (PNF) exercise were examined in 32 male university students
(aged 19-28 years). Ten repetitions of PNF exercises were applied
to the subjects' dominant upper extremities in the following order:
as an agonist pattern flexion, adduction and external rotation; and
as an antagonist pattern extension, abduction and internal rotation.
Heart rate (HR), systolic blood pressure (SBP), diastolic blood pressure
(DBP), double product (DP), and blood lactate concentration (La) were
determined before, immediately after, and at 1st, 3rd, and 5th minutes
after PNF exercise. A one-way ANOVA with repeated measures indicated
significant differences in HR, SBP, DBP, DP and La immediately after
PNF exercise. HR increased from 81 (±10) to 108 (±15)
b·min-1 (p < 0.01), SBP increased from 117 (±10)
to 125 (±11) mmHg (p < 0.01), DBP increased from 71 (±10)
to 75 (±8) mmHg (p < 0.01), DP increased from 96 (±16)
to 135 (±24) (p < 0.01), and La increased from 0.69 (±0.31)
to 3.99 (±14.63) mmol·L-1 (p < 0.01). Thus PNF exercise
resulted in increased hemodynamic responses and blood lactate concentration
that indicate a high strain on the cardiovascular system and anaerobic
metabolism in healthy subjects.
KEY
WORDS: Heart rate, systolic blood pressure, diastolic blood
pressure, double product, PNF.
|
| INTRODUCTION |
Proprioceptive neuromuscular facilitation (PNF) may be defined
as "promoting or hastening the neuromuscular mechanism through
stimulation of proprioceptors" (Knott and Voss, 1968).
PNF is widely used in physical therapy as a rehabilitation method
especially in patients with cerebral palsy and multiple sclerosis
but also used in rehabilitation of orthopaedic problems, arthritis
and peripheral nerve injuries (Livanelioglu and Erden, 1998).
PNF depends on the basic principle that human movements have rotational
and oblique characteristics, and movements against maximum resistance
result in greater muscular strength response. The amount of applied
maximum resistance can change from patient to patient and also can
vary within the same patient during different times of the day. The
most important point is to find the optimal resistance for maximum
effort. With maximal effort, motor unit firing rate increases which
result in stronger muscular contraction (Livanelioglu and Erden, 1998).
However, it is also very important that the resistance should not
result in too much fatigue in patient groups so that the movement
patterns can be followed.
It is known that repeated movements against resistance results in
fatigue, such that patients can no longer continue the movement. To
prevent or delay fatigue, different movement patterns are used during
PNF application. The movement patterns and techniques can be alternated
in a short period to prevent or delay fatigue (Voss et al., 1985).
Currently, PNF techniques are commonly used for rehabilitation and
in the area of athletic training to improve flexibility and thus improve
function and performance respectively.
During PNF, maximal resistance through the range of motion is emphasized,
using many motion combinations related to primitive movement patterns
and postural and righting reflexes (Voss et al., 1985).
These movement combinations include isometric, concentric, and eccentric
contractions together with passive movements. However, there are limited
studies examining the effect of PNF exercises on cardiovascular responses.
In an earlier study, Cornelius and co-workers (1995)
investigated the acute effects of PNF stretching techniques on systolic
and diastolic blood pressures and found that the first two trials
of PNF did not result in any significant change in blood pressure;
however, the third trial resulted in significant increase in systolic
blood pressure. Others studies have found that compared with dynamic
isotonic exercises, isometric contractions elicit marked increases
in both systolic and diastolic blood pressures, while the rise in
heart rate is less pronounced (Lind et al., 1966).
As noted, during PNF exercise patients usually fail to follow the
contraction patterns as the number of contractions increases, which
indicate local muscular fatigue in the working muscles (Livanelioglu
and Erden, 1998).
Muscular fatigue is defined as failure to maintain force or power
output during sustained or repeated contractions (Newsholme et al.,
1992).
Fatigue also limits performance, produces a general feeling of discomfort
and frustration, and interferes with well being (Kirkendall, 1990).
The underlying mechanisms of fatigue have evoked much interest for
a long time, and their significance lies not only in the function
of normal skeletal muscle, but also in diseased muscle. Studies indicate
that the cause of muscular fatigue could be central or peripheral
(Gandevia, 1998;
Westerblad et al., 1998).
One of the causes of peripheral fatigue is the accumulation of lactic
acid in the muscle that results in increased hydrogen ion concentration,
which in turn results in decreased action potentials, changes in sarcoplasmic
release of calcium, and decreased activities of muscle enzymes (Sahlin,
1986;
Kirkendall, 1990;
Newsholme et al., 1992;
Westerblad et al., 1998;
Westerblad et al., 2002).
No study related to PNF exercises and muscular fatigue has been found,
although muscular fatigue plays an important role in being able to
continue the exercise pattern(s).
Because limited research related to the effects of PNF exercises on
the cardiovascular system and muscular fatigue has been found, this
study was designed to determine the hemodynamic and blood lactic acid
responses to PNF exercise. |
| METHODS |
|
Subjects
Thirty-two healthy male university students (age 22.7 ± 2.2
years; height 1.78 ± 0.03 m; weight 74.4 ± 9.5 kg;
BMI 23.4 ± 2.87 kg·m-2) voluntarily participated
in this study. All subjects read and signed an informed consent
form approved by the Faculty of Health Sciences project committee
of Baskent University. The ethics committee of the University also
approved the study. Subjects were moderately active as their physical
activity level was 128.47 (±95.61) MET·w-1,
which was determined by the Physical Activity Assessment Questionnaire
(PAAQ), developed by Karaca and coworkers (2000)
for the Turkish population. The reliability (r) and validity (r)
of the PAAQ was 0.73 and 0.72 respectively (Karaca et al., 2000).
PNF
Exercises
Repeated contractions were applied as facilitation techniques. The
basis of this technique depends on the fact that repeated stimulation
of CNS pathways reduces synaptic resistance and improves transmission
of impulses (Voss et al., 1985).
Repeated contractions were applied to the subjects' dominant upper
extremities. Agonist patterns of flexion, adduction, and external
rotation, and an antagonist pattern of extension, abduction, and
internal rotation were used. At the start of repeated contractions,
the muscles of the dominant upper extremity were placed in the longest
position. Starting with the antagonist pattern, fingers were placed
into flexion and radial adduction, the wrist into flexion and radial
deviation, the forearm into supination, the shoulder into flexion,
adduction, and external rotation, and the scapula into rotation,
abduction, and elevation. The rationale for selecting these particular
PNF patterns was their frequent use in physiotherapy for patients
demonstrating muscle weakness and poor co-ordination (Voss et al.,
1985;
Livanelioglu and Erden, 1998).
During the arm movements that are performed over shoulder level
flexion, adduction and external rotation were selected as agonist
pattern to determine the hemodynamic loading of the exercise and
its effect on
lactate concentration (Fletcher et al., 1995).
The movements were performed from distal to proximal, during which
isometric contractions were performed with the "hold"
command at the proximal pivots. These PNF patterns were applied
for 10 repetitions, and the same tester performed all applications.
Procedures
Subjects were familiarized with the experimental procedure 1 week
prior to the experiment. Subjects performed a PNF exercise with
their dominant hand with the help of a tester, and heart rate (HR),
blood pressure (BP), double product (DP), and blood lactic acid
concentration (La) were determined before, immediately after, and
at 1st, 3rd, and 5th minutes after the PNF exercise.
Subjects' heart rates were monitored continuously throughout the
test period and were recorded prior to, immediately after, and at
1st, 3rd and 5th minutes after the PNF exercise, using a Sports
Tester Vantage (Polar Electro, Finland), short-range telemetry system.
Subjects' blood pressure was measured by auscultation of the inactive
arm prior to, immediately after, and at 1st, 3rd, and 5th minutes
after the PNF exercise, with an aneroid sphygmomanometer (Mac-Check,
Japan). Systolic blood pressure (SBP) was determined as the initial
appearance of sound, while diastolic blood pressure (DBP) was determined
as the first change in sound from sharp to muffled. Double product
(DP) (or the rate pressure product) value was calculated by the
following formula: DP = HR × (SBP/100).
Blood samples were taken from the earlobe and were analyzed by using
the YSI Sport 1500 L-Lactate Analyzer with a cell-lysing agent (Yellow
Springs Instruments, Yellow Springs, OH, USA), prior to, immediately
after, and 1st, 3rd, and 5th minutes after the PNF exercise.
Data analysis
Means and standard deviations were used as descriptive statistics.
A repeated measures ANOVA was used to compare HR, BP, DP, and La,
which were taken prior to, immediately after, and at the 1st, 3rd
and 5th minutes after the PNF exercise. For each ANOVA that resulted
in a significant F ratio, post hoc analysis was performed with Least
Significant Difference. SPSS software (Statistical Package for the
Social Sciences, version 10.0, SSPS Inc, Chicago, Illinois, USA)
was used in statistical analysis, and the level of significance
was set at p < 0.05.
|
| RESULTS |
|
Means
and standard deviations and one-way ANOVA with repeated measures
results for heart rate, blood pressure, double product, and blood
lactate concentration are given in Table
1.
The results of a one-way ANOVA with repeated measures revealed significant
differences in heart rate, systolic blood pressure, diastolic blood
pressure, double product, and blood lactic acid concentration. LSD
post hoc analysis indicated that HR, SBP and DP values obtained
after PNF exercises were significantly higher than values obtained
before PNF (for HR mean difference: 26. 188, p = 0.000; for SBP
mean difference: 7.500, p = 0.000; for DP mean difference: 38.759,
p = 0. 000) and during the 1st (for HR mean difference: 25.125,
p = 0.000; for SBP mean difference: 8.438, p = 0.000; for DP mean
difference: 38.230, p = 0.000), 3rd (for HR mean difference: 26.219,
p = 0. 000; for SBP mean difference: 10.938, p = 0.000; for DP mean
difference: 41.697, p = 0.000), and 5th (for HR mean difference:
27.125, p = 0.000; for SBP mean difference: 12.500, p = 0.000; for
DP mean difference: 43.853, p = 0.000) min of recovery period (HR:
F(4,28) = 26.459, p = 0.000; SBP: F(4,28) = 14.539, p = 0.00 and
DP: F(4,28) = 25.912, p = 0 .00). For DBP values LSD post hoc analysis
indicated that DBP values obtained after PNF exercises were significantly
higher than values measured at 1st (mean difference: 3.226, p =
0.023), 3rd (mean difference: 3.226, p = 0.033) and 5th (mean difference:
5.258, p = 0.001) min of recovery period (F(4,28) = 3.101, p = 0.032)
and for La, values obtained before PNF exercise were significantly
lower than values obtained at the 1st (mean difference: -0.712,
p = 0.000), 3rd (mean difference: -0.582, p = 0.000), and 5th (mean
difference: -0.405, p = 0.001) min of recovery period (F(4,28) =
14.407, p = 0.000).
|
| DISCUSSION |
|
In PNF exercise, repetition of activities is very important for
motor learning, strength, and endurance development (Livanelioglu
and Erden, 1998).
Repeated contraction of weak components may result in fatigue. When
the stretch reflex that appears at the initial phase of the movement
is combined with the voluntary effort of the patient, the response
is increased and fatigue is delayed (Voss et al., 1985).
Isometric and isotonic contractions in PNF techniques may result
in hemodynamic differences by affecting the cardiovascular system
(Cornelius and Craft-Hamm, 1988).
In a study by Yakut and Arikan (2001),
hemodynamic responses to PNF techniques to upper and lower extremities
were compared. Similar diagonal patterns of PNF exercise were applied
to healthy subjects and heart rate, blood pressure, and double product
values were measured at the first, fifth, and tenth PNF repetition
(Yakut and Arikan, (2001).
As the number of repetitions increased, significant increases were
found in heart rate, blood pressure and double product (p < 0.05).
The latter study indicated that PNF applications provided an additional
load to the cardiovascular system as evidenced by increased heart
rate, blood pressure, and double product. In another study (Greer
et al., 1980),
changes in oxygen consumption, heart rate, systolic and diastolic
blood pressures, and double product, were examined during PNF exercises
in patients with coronary heart disease. Increases in double product
values were higher in upper extremity exercise compared with lower
extremity exercise. Other studies agree with this finding (e.g.
Toner et al., 1983;
Wetherbee et al., 1991).
Studies related to PNF exercise generally investigate hemodynamic
responses to PNF exercises (Cornelius et al., 1995;
Yakut and Arikan, 2001),
and no previous study has been found relating the effects of PNF
exercise on blood lactic acid concentration. In the present study,
significant increases were found after repeated PNF exercise in
heart rate, systolic and diastolic blood pressures, double product,
and blood lactic acid concentration. Increased lactic acid concentration
to almost anaerobic threshold levels indicated that PNF exercises
taxes the anaerobic energy supply systems as well as the cardiovascular
system.
Muscle fatigue is defined as a loss of force and power output leading
to reduced performance of a given task (Fitts, 1993).
The nature and extent of muscle fatigue depends on the type, duration,
and intensity of exercise, the fibre type composition of the muscle,
individual level of fitness, and numerous environmental factors
(Sahlin, 1986;
Westerblad et al., 1998).
During short duration, high-intensity exercise, fatigue could result
from increased lactate accumulation and hence the increased H+ concentration
(Fitts, 1993;
Sahlin, 1986).
Concomitant with an increase in blood lactic acid concentration,
there is a decrease in the ability of the muscle to perform work.
Increased metabolic responses in the present study indicated that
PNF exercise results in an increase in blood lactic acid concentration
and may result in increased fatigue.
Increased lactate concentrations immediately after PNF exercise
indicates the anaerobic contribution inherent during this type of
exercise because of poor blood flow during PNF exercise (Powers
and Howley, 2004).
In the present study, an increased double product immediately after
PNF exercises was similar to increased lactic acid concentrations
immediately after PNF exercises. An increased double product values
after PNF exercises indicates increased myocardial oxygen consumption.
This in turn results in increased lactic acid concentration during
anaerobic exercises, such as during PNF exercises in the present
study since during isometric exercises blood flow is poor (Powers
and Howley, 2004),
because the heart has a limited ability to use lactic acid (Fletcher
et al., 1995).
During PNF exercises, different movement patterns must be used.
Duration, frequency, and intensity of the exercises must be arranged
so that responses from PNF exercises can be increased. In addition,
in patients at risk for the development of coronary heart disease,
if PNF exercises are to be used together with isometric and isotonic
contractions, care should be taken to monitor heart rate, blood
pressure, and double product values at regular intervals to prevent
untoward responses.
|
| CONCLUSIONS |
|
In conclusion,
the present study resulted in increased hemodynamic responses and
an increase in lactic acid concentration, indicating that PNF exercises
resulted in a strain on the cardiovascular system and led to increased
anaerobic metabolism in healthy subjects. Given that PNF exercises
are also applied to patients and injured athletes, hemodynamic responses
and lactic acid accumulation should be monitored carefully and intermittently
during the rehabilitation period to prevent comorbid conditions
and fatigue from developing during PNF exercises.
|
| KEY
POINTS |
-
PNF exercises resulted in increased hemodynamic responses.
- Repeated
PNF exercises resulted in an increased blood lactate concentration.
|
| AUTHORS
BIOGRAPHY |
Zuhal GÜLTEKIN
Employment: Department of Physical Therapy and Rehabilitation,
Baskent University, Ankara, Turkey.
Degree: PhD, PT.
Research interests: Physical therapy in sports.
E-mail: zuhalg@baskent.edu.tr |
|
Ayse KIN-ISLER
Employment: Department of Sport Sciences, Baskent University,
Ankara, Turkey.
Degree: PhD.
Research interests: Exercise physiology.
E-mail: akisler@baskent.edu.tr |
|
Özgür
SÜRENKÖK
Employment: Vocational School of Health Sciences, Baskent
University, Ankara, Turkey.
Degree: MSc, PT.
Research interests: Physical therapy in sports.
E-mail: ozgurs@baskent.edu.tr |
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