Radiobiology3&4
Transcript of Radiobiology3&4
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Prof.Dr.Tarek Elnimr
L 3& L4Presented to the
Biology Departments in Faculty of
Scienceson February 15 ,
2009
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Electromagnetic Waves vs. Particle RadiationRadiation
Energy transfer through matter or spaceClassification of Radiation Energy
Electromagnetic Made of electric and magnetic fields Radio, UV, microwave, gamma rays, visible light, x-
rays, and infra red (listed in order from lowest frequency)
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Spring 2008 3
Electromagnetic Radiation
Interrelated electric and magnetic fields traveling through space
All electromagnetic radiation travels at c = 3108 m/s in vacuum – the cosmic speed limit!real number is 299792458.0 m/s exactly
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Electromagnetic Spectrum
Diagram of EM spectrum (w/ color)
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Radioactivity: Gamma RaysThe Electromagnetic Spectrum
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Stratospheric Ozone and Ultraviolet Radiation (UVR)Ultra-violet radiation (UVR) high energy electromagnetic wave emitted from the
sun. It is made up of wavelengths ranging from 100nm to 400nm.
UV radiation includes UV-A, the least dangerous form of UV radiation, with a wavelength range between 315nm to 400nm, UV-B with a wavelength range between 280nm to 315nm, and UV-C which is the most dangerous between 100nm to 280nm. UV-C is unable to reach Earth’s surface due to stratospheric ozone’s ability to absorb it. (Last, 2006)
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for visible light is approximately 100 nm
red 750 - 610 nm long - low
purple 450 - 400 nm short - high
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Wavelength UnitsMeters
More commonly in nanometers (1 nm = 10-9
meters)Angstroms still used
Named for Swedish Astronomer who first named these wavelengths
1 nanometer = 10 Ao
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THE ENERGIES OF ELECTROMAGNETIC WAVES
THE ENERGIES OF ELECTROMAGNETIC WAVES
hcNc
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hcNc
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(nu-bar) represents wavenumber, the number of wavelengths in 1 cm
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4) Characteristics of Waves
- wavelength - distance between consecutive peaks - crests - measured in m, nm, angstroms.
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• All life is dependent on small doses of electromagnetic radiation.
• For example, photosynthesis and vision use the suns radiation.
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Low HighENERGY
Radio waves
Microwaves
Radar
Infrared
Visible light
Ultra-violet
X-ray
Gamma-ray
Non-ionizing radiation
Ionizing radiation
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Radiation is EnergyRadiation is EnergyThe energy is given off by unstable
(radioactive) atoms and some machines.
• For this talk, we will be focusing on ionizing radiation and its health effects.
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frequency - (nu) - number of times per second a crest passes a given point (cycles per second)
1 Hz = 1 cycle per second = 1/sec =sec-1
u = speed = X
nm/wave X wave/sec = nm/sec
for light - speed of electromagnetic radiation in a vacuum is a constant - c - 2.998 X 108 m/sec
X = c for light
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nu is inversely proportional to the wavelength. What does this mean?
The range of frequencies or wave lengths is called the electromagnetic spectrum - it ranges from gamma rays to TV, FM, AM radio waves.
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Forms of RadiationForms of RadiationWhen unstable atoms transform, they often eject particles from their nucleus. The most common of these are: Alpha Radiation
High energy, but short range (travels an inch in air, not an external hazard)
Beta RadiationLonger range (10 – 20 feet in air) and can be a skin and eye hazard for high activity beta sources.
Gamma Rays (electromagnetic radiation) Often accompany particle radiation. This “penetrating” radiation is an external hazard and can travel 100s of feet in air.
gamma
gamma
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NonionizingUltraviolet, visible, infrared, microwaves, radio & TV, power transmission
IonizingRadiation capable for producing ions when interacting with matter – x-rays, alpha, beta, gamma, cosmic rays
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NonionizingUltraviolet, visible, infrared, microwaves, radio & TV, power transmission
IonizingRadiation capable for producing ions when interacting with matter – x-rays, alpha, beta, gamma, cosmic rays
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Sources• Ultraviolet light• Visible light• Infrared radiation• Microwaves• Radio & TV• Power transmission
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• Ultraviolet – Black light – induce fluorescence in some materials
• Vision – very small portion that animals use to process visual information
• Heat – infrared – a little beyond the red spectrum
• Radio waves – beyond infrared• Micro waves• Electrical power transmission – 60
cycles per second with a wave length of 1 to 2 million meters.
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Ionizing Electromagnetic Radiation
Ionizing Electromagnetic Radiations do have enough energy to remove electrons from atoms, such as:•X-rays•Gamma rays•Neutrons•Alpha Particles
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Ionization
Atom
Electron
IonizingRadiation
Ion
More Reactive !!
Biological Effect
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The process by which a neutral atom acquires a positive or negative charge
Ionization
electron is stripped from atom
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The neutral atom gains a + charge= an ion
+
+
Alpha Particle
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IonizationIonization by a Beta particle:
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The neutral absorber atom acquires a positive charge
Beta Particle
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CollidingCoulombic Fields
ejected electron
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Radiation and Radioactive Material are a Radiation and Radioactive Material are a Natural Part of Our LivesNatural Part of Our LivesWe are constantly exposed to low levels of radiation from outer space, earth, and the healing arts.
Low levels of naturally occurring radioactive material are in our environment, the food we eat, and in many consumer products.
Some consumer products also contain small amounts of man-made radioactive material.
SmokeDetector
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Non-Ionizing Electromagnetic Radiation Non-Ionizing Electromagnetic Radiations do not have enough energy to remove electrons from atoms, such as:•Ultraviolet Radiation•Light•Infrared Radiation•Microwaves•Radio Waves
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Microwaves 3 major uses in our society
Cooking (Ovens)
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Microwaves 3 major uses in our society
Cell phones Radar
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Infrared Radiation (Heat)
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• Energy between 750 nm to 0.3 cm• The energy of heat – Heat is the transfer
of energy• Can damage – cornea, iris, retina and
lens of the eye (glass workers – “glass blower’s cataract”)
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• Energy between 400 and 750 nm• High energy – bright light produces of
number of adaptive responses• Standards are set for the intensity of
light in the work place (measured in candles or lumens)
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• Sun light• Most harmful UV is absorbed by the
atmosphere – depends on altitude• Fluorescent lamps• Electric arc welding
Can damage the eye (cornea)• Germicidal lamps• Eye damage from sun light• Skin cancer
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• High ultraviolet – kills bacterial and other infectious agents
• High dose causes - sun burn – increased risk of skin cancer
• Pigmentation that results in suntan • Suntan lotions contain chemicals that
absorb UV radiation• Reaction in the skin to produce Vitamin D
that prevents rickets• Strongly absorbed by air – thus the danger
of hole in the atmosphere
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Too much ultra-violet light can result in:Skin cancerEye damage such as cataractsImmune system damageReduction in phytoplanktonDamage to the DNA in various life-forms
this has been as observed in Antarctic ice-fish that lack pigments to shield them from the ultra-violet light (they've never needed them before)
Possibly other things too that we don't know about at the moment
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Ionization Defined
Radiation capable for producing ions when interacting with matter – in other words enough energy to remove an electron from an atom.
Sources – x-rays, radioactive material produce alpha, beta, and gamma radiation, cosmic rays from the sun and space.
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Radioactive Material
Either natural or created in nuclear reactor or accelerator
Radioactive material is unstable and emits energy in order to return to a more stable state (particles or gamma-rays)
Half-life – time for radioactive material to decay by one-half
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Hazards of Radiation“Radiation is radiation. It cannot be seen; it
cannot be felt; it cannot be smelled; it cannot be heard; and it cannot be touched. Yet it exisits, and though its proper use has been immeasurable benefit to mankind, its abuse or improper use presents great hazards.”
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The process by which a neutral atom acquires a positive or negative charge
Ionization
electron is stripped from atom
-
-
-
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The neutral atom gains a + charge= an ion
+
+
Alpha Particle
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Alpha Particles Two neutrons and two protons Charge of +2 Emitted from nucleus of radioactive
atoms Transfer energy in very short
distances (10 cm in air) Shielded by paper or layer of skin Primary hazard from internal
exposure Alpha emitters can accumulate in
tissue (bone, kidney, liver, lung, spleen) causing local damage
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Radioactivity: Beta Rays
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Beta Particles Small electrically charged
particles similar to electrons Charge of -1 Ejected from nuclei of radioactive
atoms Emitted with various kinetic
energies Shielded by wood, body
penetration 0.2 to 1.3 cm depending on energy
Can cause skin burns or be an internal hazard of ingested
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Gamma-rays Electromagnetic photons or
radiation (identical to x-rays except for source)
Emitted from nucleus of radioactive atoms – spontaneous emission
Emitted with kinetic energy related to radioactive source
Highly penetrating – extensive shielding required
Serious external radiation hazard
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X-rays Overlap with gamma-rays Electromagnetic photons or radiation Produced from orbiting electrons or
free electrons – usually machine produced
Produced when electrons strike a target material inside and x-ray tube
Emitted with various energies & wavelengths
Highly penetrating – extensive shielding required
External radiation hazard Discovered in 1895 by Roentgen
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