Prof.Dr. Gehan Mosaad - PowerPoint PPT Presentation

1 / 22
About This Presentation
Title:

Prof.Dr. Gehan Mosaad

Description:

Prof.Dr. Gehan Mosaad At the end of this lecture the student must be able to: Define electrotherapy, electric current and electromagnetic spectrum (EMS) Understand ... – PowerPoint PPT presentation

Number of Views:230
Avg rating:3.0/5.0
Slides: 23
Provided by: Dr257
Category:

less

Transcript and Presenter's Notes

Title: Prof.Dr. Gehan Mosaad


1
Electromagnetic Spectrum
  • Prof.Dr. Gehan Mosaad

2
At the end of this lecture the student must be
able to
  • Define electrotherapy, electric current and
    electromagnetic spectrum (EMS)
  • Understand the characteristics of electromagnetic
    radiation
  • Identify the different regions of EMS
  • List Physical laws governing application of
    electromagnetic radiation

3
Definitions
  • Electrotherapy can be defined as the treatment of
    patients by electrical means. It also means that
    electrical forces are applied to the body
    leading to physiological changes for therapeutic
    purpose.
  • Electric current is the flow of electric charge
    through a medium. This charge is carried by
    moving electrons in a conductor as wire, or by
    ions in electrolyte or by both ions and electrons
    as in a plasma. The unit for measuring the rate
    of flow of electric charge is the ampere.
  • Electromagnetism Electric current produces a
    magnetic field which can be visualized as
    pattern of circular field lines surrounding the
    wire.

4
Electromagnetic Spectrum
  • Electromagnetic spectrum
  • It is the distribution of electromagnetic
    radiation according to the energy ( or according
    to wavelength or frequency).
  • Electromagnetic radiation
  • It is composed of electric and magnetic fields
    that are oriented perpendicular to each other and
    to the direction of travel or radiation.
  • It covers a broad spectrum of wavelengths and
    frequencies.

5
(No Transcript)
6
Characteristics of electromagnetic radiation
  • All electromagnetic radiations have a constant
    velocity in space 300 million meters per second
    (speed of light)
  • They transport energy through space
  • They are transmitted without the need of a
    medium or conductor (self propagating).
  • They are transverse waves, may be absorbed,
    reflected and/or refracted depending on the
    medium that they strike.
  • Their direction of travel is always in a straight
    line.
  • Electromagnetic radiation is categorized
    according to its wavelength and frequency which
    are inversely proportional to each other.

7
  • The relation between wavelength and frequency
  • Wavelength The horizontal distance from one wave
    beak to the same point on the next wave.
  • Frequency The number of cycles that occurs in
    one second (cycle /second). It is measured in
    Hertz (Hz).
  • The relation between wavelength and frequency are
    governed by the formula
  • Speed of light Wavelength X frequency
  • Because the velocity is constant, there is
    inverse relationship between the wavelength and
    frequency for electromagnetic wave( the higher
    the frequency the shorter the wavelength).
  • The radiating energy is directly proportional to
    the frequency and inversely to the wavelength

8
Regions of electromagnetic spectrum
  • Ionizing range
  • Electromagnetic radiation such as x ray and gamma
    rays is ionized radiation.
  • It can break molecular bonds to form ions and
    can easily penetrate the tissue and deposit its
    energy within the cell. If the energy is
    sufficiently high, ionizing radiation can also
    inhibit cell division and eventually killing the
    cell.
  • Energy within the ionizing range is used in very
    small doses for imaging (diagnostically in X ray)
    or to destroy tissues (therapeutically in
    radiation treatment) for some forms of cancer.

9
Regions of electromagnetic spectrum
  • Non ionizing range
  • Low frequency electromagnetic radiation is non
    ionizing and can not break molecular bonds or
    produce ions and so can be used for therapeutic
    medical applications.
  • It includes
  • 1- Light spectrum as visible light, infrared
    ultraviolet
  • 2- Diathermy as shortwave and microwave
  • 3- Electric currents as electrical stimulating
    current

10
(No Transcript)
11
  • Physical laws governing the application of
    electromagnetic radiation

12
1- Reflection
  • Reflection is the return of the electromagnetic
    wave from an object. When electromagnetic
    radiations strike a surface part of the energy is
    reflected back in the same plane of the incident
    angle.
  • Incident angle Reflected angle
  • The amount of reflection decrease when the
    radiation striking the surface at right angle.

13
2-Refraction
  • Refraction refers to the change in direction of
    the radiation vector when it passes from one
    medium to another of a different density.
  • It depends on the media involved and the angle of
    incidence of the rays
  • So, the rays striking the surface at right angle
    continue in the same straight lines.

14
(No Transcript)
15
3- Absorption and penetration
  • Absorption is reciprocal of penetration as the
    greater the penetration the lesser the
    absorption.
  • Radiation must be absorbed to facilitate the
    changes within the body tissue. Absorption
    depends on the nature and type of tissue
  • The penetration of energy into a medium is
    dependent upon
  • Wavelength and frequency
  • Angle of incidence
  • Nature of medium
  • Intensity of radiation

16
4- Scattering
  • Radiation passing through non-homogenous matter
    may be partly scattered.
  • The amount of scattering depends on the
    wavelength of radiation. Longer wavelength
  • ( lower frequency) are scattered less than the
    shorter ones (higher frequency)

17
5- Inverse square law
  • This law state that the intensity of radiation
    is inversely proportional to the square of the
    distance between the source of the energy and the
    tissues.
  • The intensity of the energy striking the tissue
    depends on the distance between the source and
    the tissue.
  • According to the formula E Es / D²
  • where
  • E the amount of energy received by the tissue
  • Es the amount of energy produced by the
    source
  • D² the square of the distance between the
    tissue and the source.

18
(No Transcript)
19
6-Cosine law
  • This law state that the intensity of radiation
    varies as the cosine of the angle of incidence.
  • Effective energy Energy X cosine of the angle
    of incidence
  • Electromagnetic energy is most efficiently
    transmitted to the tissue when it strikes the
    body at right angle. As this angle of incidence
    deviates away from 90 degree, the intensity of
    radiation affecting the tissue decrease.

20
(No Transcript)
21
7-The Arndt-Schulz law
  • This law state that, no physiological changes can
    occur in body tissues, if the amount of energy
    absorbed is insufficient to stimulate the
    absorbing tissues.
  • According to this law, a certain minimum
    intensity of electromagnetic radiation is needed
    to initiate a biological process.
  • Beyond a certain level, stronger intensity will
    have a progressively less positive effect and
    become inhibitory.

22
Thank You
Write a Comment
User Comments (0)
About PowerShow.com