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Tissue Radiation Biology

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Tissue Radiation Biology Response to irradiation at the tissue level; Tied to cellular division kinetics In general cells have the same sensitivity to ionizing ... – PowerPoint PPT presentation

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Title: Tissue Radiation Biology


1
Tissue Radiation Biology
2
Response to irradiation at the tissue level
  • Tied to cellular division kinetics
  • In general cells have the same sensitivity to
    ionizing radiation as far as nuclear injury is
    concerned.
  • The DNA in all mammalian cells has about the same
    sensitivity to radiation injury.,

3
Response to irradiation at the tissue level
  • Difference in response become apparent at the
    tissue (organ) level.
  • These differences in radiation sensitivity are
    due to the rate of replication inherent in the
    critical cells in that

4
"Law" of Bergonie' and Tribondeau
  • Radiation has a more rapid (is more effective)
    effective against cell that are actively
    dividing, are undifferentiated and have a large
    dividing future.

5
Cell differentiation
  • Undifferentiated cells are precursor or stem
    cells and have less specialized functions. Their
    major role is to reproduce to replace themselves
    and to provide cells which mature into more
    differentiated cells.

6
Modified by Ancel and Vitemberger
  • The appearance of radiation damage is dependent
    on two factors 1. The biologic stress on the
    cell and 2. the conditions to which the cell is
    exposed pre and post irradiation
  • The most important biologic stress is division
    therefore rapidly dividing cells express damage
    earlier and slowly dividing cells later.

7
Cell differentiation
  • The more specialized a cells function is, the
    more differentiated it is. (examples are the
    major organ cells, muscle and neurons
  • Highly differentiated cell usually have less
    reproductive activity than undifferentiated
    cells. (examples of undifferentiated cells are
    bone marrow cells, intestinal crypt cells and
    basal cells of the skin.

8
Cell differentiation
  • Undifferentiated cells are precursor or stem
    cells and have less specialized functions. Their
    major role is to reproduce to replace themselves
    and to provide cells which mature into more
    differentiated cells.
  • Undifferentiated cells generally are actively
    dividing and have a long dividing future.

9
Rubin and Casarett
  • classification of cellular populations
  • based on reproductive kinetics
  • These classifications cells is an attempt to
    explain the difference in observed cellular and
    tissue radiosensitivity based on the reproductive
    and functional characteristics of various cell
    lines.

10
Vegetative Intermitotic Cells.(VIM)
  • Undifferentiated rapidly dividing cells which
    generally have a quite short life cycle. Examples
    are erythroblasts, intestinal crypt cells and
    basal cells of the skin.
  • Essentially continuously repopulated throughout
    life.

11
Differentiating Intermitotic Cells (DIM)
  • Actively mitotic cells with some level of
    differentiation. Spermatogonia are a prime
    example as well as midlevel cells in
    differentiating cell lines.
  • Have substantial reproductive capability but will
    eventually stop dividing or mature into a
    differentiate cell line

12
Multipotential Connective Tissue Cells
  • Cells which divide at irregular intervals often
    in response to a need. Relatively long cell life
    cycle.
  • Major examples are fibroblasts although recently
    more examples of such cells have been identified
    in a number of tissues

13
Reverting Postmitotic Cells (RPM)
  • does not normally undergo division but can do so
    if called upon by the body to replace a lost cell
    population. These are generally long lived
    cells.
  • Mature liver cells, pulmonary cells and kidney
    cells make are examples of this type of cell.

14
Fixed Postmitotic Cells. (FPM)
  • These cells do not and cannot divide.
  • They are highly differentiated and are highly
    specialized in there morphology and function.
  • May be very long lived or relatively short lived
    but replaced by differentiating cells below them
    in the cell maturation lines.
  • Examples are Neurons, muscle cells and RBCs

15
Perceived Radiation Sensitivity
  • VIM cells are the most sensitive cells to
    radiation and FPM cells are most resistant. The
    others are of intermediate sensitive in the order
    presented.
  • However, this perception is a product of the
    longer cell cycle time in more highly
    differentiated cell lines

16
Michalowski Classification
  • A more modern type of classification which
    essentially says the same thing in another way.

17
Michalowski Classification
  • Stem cells continuously divide and reproduce to
    give rise to both new stem cells and cells that
    eventually give rise to mature functional cells.
  • Maturing cells arising from stem cells and
    through progressive division eventually
    differentiate into an end-stage mature functional
    cell.
  • Mature adult functional cells that do not divide

18
(H-type)
  • There are many cell types that progress from the
    stem cell through the mature cell with
    nonreversible steps along the way. These cell
    lines are said to be hierarchical (H-type)
    populations.
  • They include bone marrow, intestinal epithelium,
    epidermis and many others.

19
F-type populations
  • There are other cell lines in which the adult
    cells can under certain circumstance be induced
    to undergo division and reproduce another adult
    cell. These cell are said to be flexible tissue
    (F-type populations).
  • Examples include liver parenchymal cells,
    thyroid cells and pneumocytes as well as others.

20
Michalowski Classification
  • These two types represent extremes and there are
    many tissues which exhibit characteristics of
    both types where mature cells are able to divide
    a limited number of times.
  • The rapidity of response to and hence the
    sensitivity to radiation at the tissue level is
    dependent on the length of the life cycle and the
    reproductive potential of the critical cell line
    within that tissue.

21
Critical Cells"
  • All tissues contain multiple cell types contained
    in either the stromal compartment or the
    parenchymal compartment.
  • A cell in either compartment may be the critical
    cell.

22
Critical Cells"
  • the endothelial cells lining the blood vessels
    were thought for many years to be the critical
    cells in tissues however
  • "critical cells" have been identified in many
    tissues.

23
The time required for the tissue to respond to
radiation injury can be predicted on the basis of
the cell cycle kinetics of these critical cells.
24
Biologic Factors moderating Cell injury by
irradiation.
  • Cell Cycle.
  • Intracellular repair
  • Hypoxia

25
Cell Cycle.
  • The point that a cell is in the cell cycle has a
    marked influence on its response and survival of
    irradiation.
  • G1 G0 are relatively insensitive to radiation
    injury.
  • S phase is generally considered to be the most
    resistant to radiation injury.

26
Cycle Phase Influence on Sensitivity
27
Intracellular repair
  • The shoulder on the cell survival curve indicates
    that there is some degree of repair by cells of
    radiation injury.
  • Amount of repair differs between cell lines
  • However the rate of repair is the same

28
Intracellular Repair
29
Intracellular repair
30
Intracellular repair
  • Studies have shown that although repair can be an
    ongoing process, the vast majority of the repair
    is finished by 6 hours post irradiation.
  • Once repair is complete the remaining cell
    population will respond to subsequent dose of
    radiation as though the original irradiation had
    not occurred

31
Hypoxia
  • Oxygen is a potent preventer of repair
  • Hypoxia markedly improves the ability of the
    cells to repair radiation injury
  • However it is quite rare for a normal somatic
    cell to be hypoxic.

32
Measurement or radiation injury at the tissue
level
  • Assay systems are needed to construct survival
    and injury curves for irradiation at the tissue
    level.
  • Such assays must be quantifiable
  • The effect measured must increase with dose

33
Types of Assays
  • Clonogenic (related to reproductive potential of
    stem cells in the tissuse target cell population
  • Specific tissue functional capability
  • Lethality - death of the organism from radiation
    of that tissue

34
Clonogenic assays
  • May be performed in vivo or in vitro
  • In an in vitro assay cells are harvested from
    tissue irradiated in living tissue and the cells
    are grown out in cell culture and the number of
    colonies growing out is compared to that for a
    control
  • In vivo assays are performed by evaluation of
    cellular reproductive activity in the living
    animal

35
In Vitro Assays
  • Cells harvested from culture and plated out
    many, many flasks or dishes
  • Dishes are irradiated at different levels
  • The number of colonies are counted after a
    specific time.
  • of colonies compared to control sample
  • Survival curves generated

36
In vivo Assays
  • Two types
  • In Situ Assays
  • Transplantation Assays

37
In Situ Assays
  • The tissue or organ is irradiated in the whole
    animal. At a given time after irradiation the
    organism (animal or plant) is sacrificed and the
    organ of interest is evaluated for cell survival
    of the cell of interest.
  • Classic example is the intestinal crypt cell
    studies

38
In Situ Assays
  • Another example is irradiation of testes and then
    assaying the testicle for surviving spermatogonia
    in the tubules of the testicle.

39
In Situ Assays
  • Classically these assays have been used to
    evaluate the radiation effects in acutely
    responding (rapidly dividing) cell lines such as
    the intestinal villi, the testes and the skin.
  • Recently these types of assays have been extended
    to evaluation (slowly dividing) cell lines.

40
In situ Assays
  • These assays have shown that the Do for slowly
    dividing cells in this assay is about 1.5 Gy or
    about the same as for the rapidly responding
    tissues. The difference in time required for the
    cell killing to occur is a manifestation of the
    slow turnover rate of the cells.

41
In Situ Assays
  • Tissue is irradiated in vivo and returned to
    subject.
  • After a period of time the number of viable cell
    groups in irradiated area is measured
  • Generally done in mice as large numbers are
    required.
  • Intestinal and gonadal epithelium are the classic
    tissues studied.

42
In Situ Assays
  • Studies of RPM and FPM tissues and cell lines
    requires much longer experiment
  • May require use of larger more expensive and long
    lived animals
  • These studies are very expensive to do

43
Transplantation Assays
  • Often used to study tumor sensitivity
  • Usually done in immune compromised animals.
  • Done to mimic metastatic disease or to remove
    immune system effects in live animal

44
Transplantation Assays
  • Tumor or test tissue is irradiated while still in
    donor animal.
  • Irradiated tissue is then removed and cells
    suspended in solution.
  • Cells then injected into recipient animal
  • After a period of growth, the animals are
    sacrificed and the number of tissue colonies or
    size of colony is measured.

45
Functional Assays
  • Measure organ functional capacity
  • Most organs have clinical functional reserve
  • Tests measure complete functional capacity
  • Done in a live animal with in situ organs
  • Do not require sacrifice of the animal
  • Multiple dose levels can be studied
  • Measure effect at sub clinical levels.
  • Heart, lungs, liver, kidneys applicable

46
Functional Assays
  • Measure effects of regional irradiation
  • Very important in radiation therapy
  • Helps predict effects of irradiation plan
  • Also used to study effects of ingested
    radionuclides either medical or accidental
  • Useful for studies on effect modifiers such as
    chemotherapy.

47
Lethality Assays
  • Measures clinical effects
  • Measures doses required to cause death.
  • Whole body irradiation
  • Regional body irradiation (brain, heart, liver,
    etc.
  • Generally expressed in terms of death in a
    given time. i.e. LD30/90
  • 30 of subjects die by 90 days post irradiation
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