Radiation Biology (HTI 5007) MSc Notes PDF

Summary

These are lecture notes from a Radiation Biology course (HTI 5007) at the Hong Kong Polytechnic University. The notes cover fundamental concepts of radiation biology, looking at radiation interaction with matter, consequences, sources, and aspects of medical physics. The course material is for a postgraduate (MSc) level student.

Full Transcript

Radiation Biology
(HTI 5007)
Introduction to Radiobiology and Basic Cell Biology

Dr LIN, Liang-Ting
 What are the consequences after exposure?
I stared into the microwave oven too long watching my lunch, and I
will increase the risk of blindness.
I text my friends all night long and play games until midnight, so I will
be irradiated by my cell phone and get sick.
I ate the suspected radioactive foods imported from Fukushima,
Japan, so I will be contaminated and sickened.
I went physical exam and took an X-ray exposure on Chest, my DNA
will break and my cells will mutant that may cause sickness.

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 What’s your view?

Courtesy of HK01 and BBC news
 That’s why radiobiology essential
Have you ever been exposed to radiation?
What do you feel immediately?
- Pain? Discomfort? Being penetrated?
What do you feel after a while?
- Sore? Itch? DNA breakage? Become green when getting angry?
- Side effects?
The interaction between radiation and biology

Medical Physicists work closely with radiation-associated biological
effects, particularly in the aspects of Radiotherapy.
Radiographers use radiation for medical imaging purposes

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 Overview of the Radiobiology
Is a science describing radiation effect on living organisms:
sequence of events that follows the absorption of energy from
ionizing radiation
efforts of organism to compensate the effects
consequences to the organism/system
Levels of effects:
Molecules
Cells
Tissues
Organs
Systems
Whole body

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https://www.thinglink.com/scene/412817984508133378
Overview of the Radiobiology

Those keywords in Radiobiology from the bench side to bedside

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 Levels of the radiation-induced events
Molecule: free radicals, DNA, Proteins

Cell: chromosomal aberrations, mutation, cell death,
immortalization(carcinogenesis)

Tissue/Organ: Cancer, necrosis, dysfunction, malfunction,
pathogenesis

Systemic/Whole body: complications, death

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 Game theory – it’s gambling

All radiation-induced biological events are in a function of probability.
Cannot predict individual event
Events are non-selective and random
May happen together
Stochastic effects
Cancer
Deterministic effects
Cataract

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 Where does the radiation come from?
Natural
Universe/Outer space
Inner core of the earth/underground
Radioisotope
Sounds
Magnetic fields
Artificial
Nuclear power plants
Radioisotopes from cyclotron/generators
Weapons
Radio-frequency waves
Electro-magnetic fields
 When do radiation sources enter our lives?

The sources of radiation – background radiation
Medical needs (over 90% in artificial radiation)
X-ray
Radioisotopes Only 15% belong to artificial radiation
Industrial application
Power generation
Examination
Transportation
Museum
Custom
 Medical exposures – radioisotopes

Time, Decay, Distance, Shielding
https://www.slideshare.net/Tunoo/rad-safety-at-hospitals-v-07-25jun2010-peternyan
 What is Radiation, by definition?
The energy transfer from one point to another through vacuum
Ionizing radiation vs. non-ionizing radiation
Ionizing radiation interacts with the medium of transmission
The biological effect depends on the amount of energy deposited

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 Interaction – waves interact with matters
Photoelectric effect (< 0.5 MeV)

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 Interaction – waves interact with matters
Compton effect (100 keV ~ 10 MeV)

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http://hyperphysics.phy-astr.gsu.edu/hbase/quantum/compton.html
 Interaction – waves interact with matters

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Griselda Saldana-Gonzalez et al. High Density Devices Applied to a Gamma-Camera Implementation, Advanced Image Acquisition, Processing Techniques and Applications, Dimitrios Ventzas, IntechOpen, DOI: 10.5772/33990.
 Interaction – waves interact with matters
Pair Production (> 1.022 MeV)

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http://electrons.wikidot.com/pair-production-and-annihilation
Interaction – the energy talks

1.022 MeV

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 Interaction – law of conservation of energy

What is the common product in the 3 different interaction processes of x-ray
with matters? How many are the products?

Where do these effects impact in radiological sciences?

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Griselda Saldana-Gonzalez et al. High Density Devices Applied to a Gamma-Camera Implementation, Advanced Image Acquisition, Processing Techniques and Applications, Dimitrios Ventzas, IntechOpen, DOI: 10.5772/33990.
 Interaction – Why 0.511? Why 1.022?
Photoelectric effect – the energy is able to release a photoelectron
from its atomic binding energy, no scattering

Compton scattering – the energy reaches the theoretical overall
energy of an electron, recoiled electron and scattered photon
occurred after collision

Pair production – the energy reaches the theoretical combined
energy of 2 electrons; a pair of electron and positron will occur via
collision into nucleus.

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Basic Cell Biology
 What about “Biology” in Radiobiology?
The basis of biology is “cell”

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https://emsom.edu/anatomy-physiology-cell/
 The discovery of DNA structure
1953 James Watson & Francis Crick published the double helix
structure of DNA
1962 Nobel Prize Laureate

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The discovery of DNA structure

Rosalind Franklin (1920-1958)

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 The discovery of DNA structure

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https://www.genscript.com/dna.html (modified)
 The DNA structure – a double helix model

2

3

Purine: Adenine and Guanine
Pyrimidine: Cytosine and Thymine
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https://openoregon.pressbooks.pub/mhccmajorsbio/chapter/dna-structure/
 Deoxyribonucleic Acid (DNA) Structure

DNA is a chain of nucleotides linked by covalent
bonds (sugar-phosphate bond)
Hydrogen bonds connect two strands of DNA in
the paring of A=T and C≡G.
DNA twisted into double-helix
The width between the two strands is about 2 nm
Condensed into visible chromosome during
mitosis (M phase)

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From DNA to Chromosome

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 Normal cells vs. cancer cells

The critical target in cell
Deoxyribonucleic Acid (DNA)
Are they reversible?

The ability of keeping alive
Immortalization
Non-stop cell division
Cell cycle
Telomere elongation

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 The life of cycle in cells

Quiescent (Q) stage

M: mitotic phase; I: interphase

Proliferative (P) stage
 Cellular Checkpoints – Controlled Growth

CyclinD1/Cdk4/6 (G1 progression);
CyclinE/Cdk2 (G1/S transition);
CyclinA/Cdk2 (S progression and S/G2 transition);
CyclinB/Cdk1 (G2/M transition and M progression)
 Cell cycle – checkpoints secure cell integrity
Checkpoints
‐ Cell cycle progression is regulated by several proteins as being the Go/no-Go criteria.
‐ The stoppage of cell cycle is to assure the cell contents are intact to enter mitosis
‐ G1/S checkpoint
❑ Clear to initiate DNA synthesis
‐ G2/M checkpoint
❑ DNA is correctly synthesized
❑ Clear to enter mitosis
‐ Mitotic checkpoint
❑ Spindle fibers well-attached
❑ Chromosome can be separated
Cell cycle – as an example in cancer
G1 phase progression – molecular views

R

Static state/Quiescent Proliferation-activated
 Cancer – cell doubling time (CDT)
Time required for a group of tumor cells to double the number =
around the time for one cell cycle
The CDT of cancer cells are about
24 hours
Somatic cells may not initiate
cell cycle but stay in G0 phase
eternally.
E.g. skin cells or neuron cells

https://study.com/academy/lesson/what-is-interphase-definition-stages-quiz.html
 Cancer – Tumor Growth Fraction (TGF)
There are actually very few situations in which all the cells in a
population are proliferating.
The population is consisted by proliferative (P) and quiescent (Q)
cells.

𝑵𝑷 𝑪𝒆𝒍𝒍𝒔 𝒊𝒏 𝒄𝒆𝒍𝒍 𝒄𝒚𝒄𝒍𝒆
𝑻𝑮𝑭 = =
𝑵𝑷 + 𝑵𝑸 𝑪𝒆𝒍𝒍𝒔 𝒊𝒏 𝒄𝒆𝒍𝒍 𝒄𝒚𝒄𝒍𝒆 + 𝑮𝟎
 Take home message – Biology
Rough cell cycle: Proliferative phase (P) and Quiescent phase (Q).
Cell cycle phases: G1, S, G2, and M.
(G0 is considered a long-term G1).
With in mitotic phase (M): prophase, metaphase, anaphase, and
telophase.
DNA structure is double helix with A-T and C-G pairing, where A-T are
double and C-G are triple hydrogen bonds, respectively.
Pyrimidine and purine

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 Death of cell – why cells go dying?
Programmed cell death – signaling transduction
Nutrient deprivation
Catastrophic malfunction
Irreversible damage / massive damage
Aging

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Death of cell – an end of cell life

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 Death of cell – Senescence
Aging of cells
Length of telomere – a setback of DNA replication
Nobel Prize in Physiology and Medicine (2009)

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 Death of cell – autophagy
Autophagy
Auto- : means “self”
-phagy: means “to eat”
Self-eating mechanism in cells
Nobel prize in Physiology and Medicine (2016)
Yoshinori Ohsumi (大隅 良典)
To clean up wastes/malfunction organelles
To regain energy from material recycling

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Courtesy of Nobel Prize Committee of Karolinska Institute
 Mitotic death – unable to divide

Masawang, K., M. Pedro, H. Cidade, R.M. Reis, M.P. Neves, A.G. Correa, W. Sudprasert, H. Bousbaa, and M.M. Pinto, Evaluation of 2',4'-dihydroxy-3,4,5-trimethoxychalcone as antimitotic agent that
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induces mitotic catastrophe in MCF-7 breast cancer cells. Toxicol Lett, 2014. 229(2): p. 393-401.
 Death of cell – Programmed cell death (PCD)
Why is cell death essential?
‐ Tadpole’s tail
‐ The formation of fingers and toes
‐ The sloughing off of the inner lining of the uterus
‐ The formation of proper connection between neurons and target cells in brain
‐ Apoptosis

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 Apoptosis – what program?
e.g. ionizing radiation

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Cuda, C.M., R.M. Pope, and H. Perlman, The inflammatory role of phagocyte apoptotic pathways in rheumatic diseases. Nat Rev Rheumatol, 2016. 12(9): p. 543-58.
 Apoptosis – in sequence

1. Cell shrinkage
2. Organelle breakdown
3. Mitochondrial leakage
4. Chromatin condensation
5. Nuclear fragmentation
6. Membrane blebbing

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 Death of cell – Necrosis (in tissue)
External factors:
‐ Mechanical trauma
‐ Damage to blood vessels
‐ Burn of extreme cold
‐ Ionizing Radiation
Internal factors:
‐ Internal cell injury
‐ Toxins or pathogens
e.g. snake venoms, bacterial toxin
‐ Involve activity of immune system

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https://imgur.com/gallery/ice4w
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 Categorization – Necrosis vs. Apoptosis

Higher Dose Lower Dose

Passive process Active process

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Death of cell – Summary
Necrosis Apoptosis
Higher damage Lower damage
Damage-induced Spontaneous
Cellular swelling Cellular shrinkage
Membrane rupture Membrane remains intact
ATP is depleted Energy consuming
Cell lysates outburst Apoptotic body recycled
DNA catastrophic degraded DNA fragmentation – ladder like
In vivo, bystanders affected In vivo, individually affected
Explode the house Deconstruction of the house
Death of cell – an end of cell life

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