This document provides an overview of laser therapy. It discusses the introduction, properties, types, wavelengths and components of laser production. The physiological and therapeutic effects of laser therapy are explained, along with its use for conditions like wound healing and musculoskeletal disorders. The document also covers the principles of laser application, including dosage parameters and potential dangers. It concludes by listing the most commonly used laser types and their wavelengths.
2. Introduction of laser
Properties
Types
Wavelenth
Component of laser production
How laser produce
Physiological effects
Therapeutic effects
Use and effecs of cold laser
Indication and Contraindication
Principles of application
Dosage parameters
Danger.
3.
4.
5. 1.Monochromaticity: This means that the laser light has
a single colour , mono means single chromaticity
means coloration. This is because the lasers are of a
single wavelength and thus the definite frequency .
2. Coherence : Laser radition are not of the same
wavelength but also has same phase. Coherence means
similar or synchronous behavior of laser beam.
3.Collimation: Laser beams remain collimated that
means they remain in parallel. They do not diverge
much and the energy can be propagated over a larger
distance ( Jagmohan , 2012).
6. Most commonly used laser are :
1.Ruby laser / Crystal laser
2.Helium-neon laser / Gas laser
3.Diode laser /Semiconductor laser
10. Component of laser production:-
1.Lasing medium: The material which is capable of
producing laser is known as lasing medium.
2. Resonating chamber: The resonating chamber
contains the lasing medium which is surrounded by
two parallel mirrors at either ends.One of the mirror
has 100%reflectanace while the other has slightly less
reflectance .
3. Energy source : A flashgun is used to excite the
electrons of the lasing medium. The source of flashgun
is usually current electricity.
11.
12. A tube filled with a gaseous mixture of helium and
neon is stimulated electrically to emission level.
Within the highly reflexive, polished walls of the tube ,
the molecules reverberate the carom off the walls of in
a highly agited state, building energy as the do so .
When a critical level is reached , the flow of energy
“Brust” through the semi silvered front end of the tube
and is channeled along an optic fiber to the beam
applicator or for clinical applications( Jagmohan, 2012).
21. For musculoskeletal disorders the efficacy seems
to be better than for a placebo treatment .For
rheumatoid arthritis,post traumatic joint disorder
and myofascial pain, laser therapy seemed to
have a substantial therapeutic effect.
In a study of use of laser laser therapy in clinical
practice,found that over 50% of respondents felt
that soft tissue injuries and wound healing
including burns responded particularly well to
treatment (John 2000).
22. Preparation of the patient : Explain the
patient about nature of the treatment and aware
to wear goggles or spectacles.
Preparation of the apparatus: The surface of
the skin to be treated is cleaned with an alcohol
wipe in oder to remove any material on the
surface that might absorb or scatter the radiation
. The part is supported in such a way that any
pressure of the laser applicator does not cause
movement or discomfort.
23. Application: A key usually activate the
machine and ensures that unauthorized people
do not switch the laser on .The laser applicator is
applied to the surface before switching on .It is
important to maintain the laser applicator in
contact with the tissues so that the beam is
applied at right angle in oeder to achieve
maximum penetration.
If , contact is not desired , for example because of
an infected wound , the applicator may be held
just off the surface or covered with transparent
non reflective film.
24.
25. In all other circumstances firm contact should be
maintained throughout treatment but should
not provoke pain where tenderness is present .
The position is maintained for the necessary time
.
Termination: The device is switch off before
removing the applicator from skin contact. The
details of dosage and any patient response ,such
as immediate increase or decrease pain are noted
and recorded,plus the parameters of dosage
(Jhon, 2000).
26. Wavelength:It depends on the lasing medium
used-
(a). Visible red laser : Used for superficial
conditions like wound and ulcers.
(b). Infrared laser :Used for deep condition such
as muscles and bone.
(c) Cluster probe laser: It having several diodes
and are used for larger area of soft tissues.
27. Power: The power output is measured in
watts.Therapeutically quit small mW power
output of laser beam is used.
Energy: The energy delivered to the treatment
tissue is expressed in Joules. It is calculated by
the following equation:
Energy(in Jouls)=Power(in Watts) x Times(in
Sec).
28. Power density: Power density is decreases as
the area between the tip of the applicator and
the part to be treated increases.
Total power used therapeutically is thus
calculated by the inverse squre law.
Energy density:Energy density can be
calculated as:
Power(W) x Time(sec)
Energy density= Area ( in cm2)
The dosage in laser therapy is calculated in
terms of energy density applied which is
expressed in joules/cm2 (Jagmohan, 2012).
29. 1.The main danger involvg LASER therapy is a
risk of eye damage if the beam is directly
applied into the eye.
2.It is also dangerous that the LASER beam can
be almost totally reflected from any shiny
surface(Jhon,2000).
30. 1.John Low & Ann Reed (2000).Electrotherapy
Explained Principles and Practice, Third
edition. A devision of Reed Educational and
Professional Publishing Ltd.
2.Jagmohan Singh (2012).Textbook of
Electrotherapy, Second edition. Jaypee Brothers
Medical Publisher LTD.
3. Alexandra Schnee( 2009).Web page –Spine
Health.