LC1 HYDROTHERAPY.pdf

Full Transcript

HYDROTHERAPY

Dr. Hend Ahmed Saad
Lecturer of physical therapy for women health
Objectives:
Define hydrotherapy and explain its importance.
Describe the benefits of water in any form or
temperature.
Prepare a description of Physical principles of
hydrotherapy.
Determine the sequential nature of a variety of
aquatic exercises.
 Hydrotherapy
▪ Hydrotherapy is a Greek words hydro means "water" and therapeia
means "healing".

▪ Hydrotherapy is defined as: therapeutic modality that uses water in any
form or temperature (hot, cold, steam, liquid, ice) for the treatment of
physical or psychological dysfunction.

▪ Hydrotherapy is specifically designed to improve neuromuscular,
skeletal and proprioceptive functions in patients with acute,
subacute and chronic disabilities.
 Physical principles of Hydrotherapy
1. Buoyancy / Specific gravity
2. Hydrostatic pressure
3. Viscosity and Resistance
4. Turbulence:
5. Moment of Force
6. Specific heat
7. Thermal conductivity
 Physical principles of Hydrotherapy
1. Buoyancy / Specific gravity:
Buoyancy is a force experienced as an upward
thrust on the body in the opposite direction to the
force of gravity.

According to The Archimedes Principle
states that when a body is entirely or partially
immersed in fluid at rest, it experiences an
upward thrust equal to the weight of the fluid
displaces.
Buoyancy / Specific gravity
 Buoyancy / Specific gravity

▪ The amount of fluid displaced
depends on the density of the immersed
body relative to the density of the fluid.

▪ Specific gravity is the ratio of the density of
a substance to the density of water.
▪ Water has specific gravity of 1.0 at 4°C, and
the human body has a specific gravity of
0.974.
 Buoyancy / Specific gravity

▪ Buoyancy is used to help weakened body parts to rise against
gravity or to assist the therapist in supporting the weight of
the patient's body during therapeutic activities.

▪ The buoyancy of the body in water is used clinically to
decrease stress and compression on weight-bearing joints,
muscles and connective tissue.
 Clinical implication of buoyancy:
▪ Weight relief depending on the proportion of the body below
water level:
When the body is immersed to waist level, the weight relief is
approximately 50% of the body weight.

If the water is at shoulder level, weight relief is approximately
90% of the body weight.

So pain due to weight bearing can be relieved in hydrotherapy
pool.
▪ Weight relief depending on the
proportion of the body below
water level:
 Clinical implication of buoyancy:
▪ Progression in muscle power:
A) By changing the position of the patient in the pool.

B) By changing the length of the lever arm, a flexed limb
is less assisted or resisted by the water than a straight
limb.
C) Alteration of the shape: as if we asking the patient to
hold a ball in the hand will result in alteration in
the shape of the limb, so this increase the resistance
to movement.
Starting position for stretching hip Alternative position for stretching
flexors by using floats hip flexors by using floats

Stretching hip adductors using floats
 2. Hydrostatic pressure
Defined as : the pressure exerted on an immersed
body by the water that surrounds it.

According to Pascal's law: a fluid exerts equal
pressure on all surfaces of a body at rest at a given
depth, and this pressure increases in proportion to the
depth of the fluid.
 Hydrostatic pressure

Water exerts a pressure of 22.4 mm Hg/1.36 cm
(0.54') H2o depth. Therefore, a body immersed
to a depth of 48 inches is subject to a force equal to
88.9 mm Hg, slightly greater than human diastolic
blood pressure.

Since pressure increases as depth increases, a pressure
gradient exists between shallow and deeper water;
standing in water can assist patients with lower
limb edema by encouraging fluids in higher-pressure
areas to flow proximally.
 Hydrostatic pressure

Hydrostatic pressure can be used to apply resistance if
doing exercise.
Also hydrostatic pressure of water will vary with patient
positioning. The greater effects will occur with vertical
positioning.
Hydrostatic pressure and buoyancy together can
facilitate improvement of balance activities.
Pressure gives the body support and buoyancy can assist
in maintaining an upright position if it deviates from the
vertical.
 3. Viscosity and Resistance
Viscosity is the internal friction that occurs
between molecules of water.
As a body moves through water, there is a
resistance to the motion of body in water.
Resistance in water is 42 times greater than in air.
The viscosity of water makes it a useful
strengthening medium because resistance
becomes greater as more force is exerted
against it.
 4. Turbulence:

Eddy currents result from moving in water.
The more vigorous the Movement (and the more people
moving), the greater the turbulence created.
It may be created by an under water douche, or
may be created by the physiotherapist moving through the
water.
The massaging action of the water on the skin is
pleasurable for most people. It enhances circulation,
improves venous return and reduces pain.
 5. Moment of Force
Moment of force is the turning effect of a force about any point.
The moment of force is defined as the product of the force and
the
perpendicular distance between the line of action of that force
and the fulcrum.
 A float is attached to his hand and the elbow is flexed to a right angle
The moment of force =AB x F
AB, is the perpendicular distance between the line of action of the force
and the fulcrum.
F, is the result of buoyancy acting on the floats.
 6. Specific heat

Specific heat is the amount of heat energy required to raise
unit mass of material by 1°C.

The specific heat capacity of water is equal to 1.

The specific heat capacity of air is 0.001.

Given these specific heat capacities, it is apparent that water holds
heat well, approximately 1000 times more than an equivalent
volume of air.
 7. Thermal conductivity

Thermal conductivity is the ability of a tissue to absorb
heat and conduct it across the tissue.
Water is 1000 times more dense than air. It retains and
transfers heat far better than air.

Water efficiently conducts heat. In fact, water conducts
heat 25 times faster than air does.

Water retains four times as much thermal energy
as an equivalent mass of air at the same
temperature, and it transfers this thermal energy 25
times more rapidly than air at the same
temperature.
 Thermal conductivity
Exercise in warmer pools (87°F - 98°F) should not be
too vigorous, since there will be no opportunity to lose
heat created by the working muscles.

In warm pools, participants should drink cool water,
and focus on muscle conditioning and flexibility
exercises, rather than vigorous cardiovascular training.
These pool temperatures are ideal for gentle aqua and
rehabilitation classes.
In water that is very cool (below 80°F), blood is
shunted toward the core of the body to maintain body
heat. As the water gets colder, muscles work less
efficiently.
 Any Question
Thank you …… Dr/ hend