1. Radiobiology for the Radiologist, Hall, 7th ed
Chapter 3. Cell Survival Curves
2012.04.10
Dahoon Jung
Korea Cancer Center Hospital

3. 100
balls

4. 10 x 10 lattice

6. Discrete probability distribution
Given number of events
In a fixed interval of time and/or space
Known average rate
Independently of the time since the last event
k is the number of occurrences of an
event — the probability of which is given by
the function
λ is a positive real number, equal to
the expected number of occurrences during
the given interval.
Simeon Denis Poisson(1781-1840)

7. Overview
• Reproductive Integrity
• The In Vitro Survival Curve
• The Shape of the Survival Curve
• Mechanisms of Cell Killing
– DNA as the Target
– The Bystander Effect
– Apoptotic and Mitotic Death
– Autophagic Cell Death
– Senescence
• Survival Curves for Various Mammalian Cells in Culture
• Survival Curve Shape and Mechanisms of Cell Death
• Oncogenes and Radioresistance
• Genetic Control of Radiosensitivity
• Intrinsic Radiosensitivity and Cancer Stem Cells
• Effective Survival Curve for a Multifraction Regimen
• Calculations of Tumor Cell Kill
• The Radiosensitivity of Mammalian Cells Compared with Microorganisms

8. Reproductive Integrity
• Cell survival curve describes the relationship
between the radiation dose and the proportion of
cells that survive.
– Cell ―Death‖ : loss of reproductive integrity
• Clonogenic : survivor able to proliferate
indefinitely to produce a large clone or colony

9. Reproductive Integrity
• Mitotic death : death while attempting to divide(dominant
following irradiation)
• Apoptosis : programmed cell death
• In general, a dose of 100 Gy is necessary to destroy cell
function in nonproliferating systems.
• By contrast, the mean lethal dose for loss of proliferative
capacity is usually less than 2 Gy.

10. The In Vitro Survival Curve

11. The In Vitro Survival Curve

12. The Shape of the Survival Curve
• At ―low doses‖ for sparsely ionizing (low-linear energy
transfer[LET]) radiations, such as x-rays, the survival
curve starts out straight on the log-linear plot with a finite
initial slope.
– The surviving fraction is an exponential function of
dose.
• At higher doses, the curve bends.
• At very high doses, the survival curve often tends to
straighten again. (usually not occur in RT)

13. The Shape of the Survival Curve
A:The linear quadratic model. B:The multitarget model.
A. Good fit to experimental data for the first
few decades of survival.

14. The Shape of the Survival Curve
• For densely ionizing (high-LET) radiations, such as α-
particles or low-energy neutrons, the cell survival curve
is a straight line from the origin.
• Many attempts to deduce a curve shape that is
consistent with experimental data, but it is never possible
to choose among different models or theories based on
goodness of fit to experimental data.

15. The Shape of the Survival Curve
• 1. The multitarget model
– D1 : initial slope(from single-event killing)
– D0 : final slope(from multiple-event killing)
– n or Dq : the width of the shoulder
– D1, D0 are the dose required to reduce the fraction of surviving
cells to 37% of its previous value.
• Ex) D1 : 1  0.37 , D0 : 0.1  0.037 or 0.01 to 0.0037
– The surviving fraction is on a logarithmic scale and the survival
curve becomes straight at higher doses, the dose required to
reduce the cell population by a given factor (to 0.37) is the same
at all survival levels.
(On average, the dose required to deliver one inactivating event per cell.)

16. The Shape of the Survival Curve

17. The Shape of the Survival Curve
• 2. The linear-quadratic model
– Direct development of the relation used to describe
exchange-type chromosome aberrations that are
clearly the result of an interaction between two
separate breaks.
– Assumes that there are two components to cell killing
by radiation.
• One that is proportional to dose
• One that is proportional to the square of the dose

18. The Shape of the Survival Curve

19. The Shape of the Survival Curve
• The components of cell killing that are proportional to
dose and to the square of the dose are equal if
αD = βD2
or
D = α/β
• The linear and quadratic contributions to cell killing are
equal at a dose that is equal to the ratio of α to β.
• A characteristic of the LQ formulation is that the resultant
cell survival curve is continuously bending; there is no
final straight portion.

20. Mechanisms of Cell Killing
<DNA as the Target>
• The principal sensitive sites for radiation-induced cell
lethality are located in the nucleus as opposed to the
cytoplasm.
• The evidence implicating the chromosomes, specifically
the DNA, as the primary target for radiation-induced
lethality may be summarized as follows:

21. Mechanisms of Cell Killing
• 1. Cells are killed by radioactive tritiated thymidine
incorporated into the DNA. The radiation dose results
from short-range α-particles and is therefore very
localized.

22. Mechanisms of Cell Killing
• 2. Certain structural analogues of thymidine, particularly the
halogenated pyrimidines, are incorporated selectively into DNA in
place of thymidine if substituted in cell culture growth medium.
This substitution dramatically increases the radiosensitivity of the
mammalian cells to a degree that increases as a function of the
amount of the incorporation. Substituted deoxyuridines, which
are not incorporated into DNA, have no such effect on cellular
radiosensitivity.

23. Mechanisms of Cell Killing
• 3. Factors that modify cell lethality, such as variation in
the type of radiation, oxygen concentration, and dose
rate, also affect the production of chromosome damage
in a fashion qualitatively and quantitatively similar. This is
at least prima facie evidence to indicate that damage to
the chromosomes is implicated in cell lethality.

24. Mechanisms of Cell Killing
• 4. Early work showed a relationship between virus size
and radiosensitivity; later work showed a better
correlation with nucleic acid volume. The radiosensitivity
of a wide range of plants has been correlated with the
mean interphase chromosome volume, which is defined
as the ratio of nuclear volume to chromosome number.
The larger the mean chromosome volume, the greater
the radiosensitivity.

25. Mechanisms of Cell Killing
<The Bystander Effect>
• Defined as the induction of biologic effects in cells that
are not directly traversed by a charged particle, but are
in proximity to cells that are.
• Nagasawa and Little, 1992
– Low dose of α-particles, a larger proportion than estimated of cells
showed an biologic change.

26. Mechanisms of Cell Killing
• The use of sophisticated single-particle
microbeams, which make it possible to deliver a known
number of particles through the nucleus of specific cells.
• The bystander effect has also been shown for protons
and soft x-rays.
• The effect is most pronounced when the bystander cells
are in gap-junction communication with the irradiated
cells.
• For example, up to 30% of bystander cells can be killed
in this situation.

27. Mechanisms of Cell Killing
• The effect being due, presumably, to cytotoxic molecules
released into the medium.
• The existence of the bystander effect indicates that the
target for radiation damage is larger than the nucleus
and, indeed, larger than the cell itself.
• Its importance is primarily at low doses, where not all
cells are ―hit‖.

28. Mechanisms of Cell Killing
• In addition to the experiments described previously
involving sophisticated single-particle microbeams, there
is a body of data involving the transfer of medium from
irradiated cells that results in a biologic effect(cell killing)
when added to unirradiated cells.
– Suggest that irradiated cells secrete a molecule into the medium
that is capable of killing cells when that medium is transferred
onto unirradiated cells.

29. Mechanisms of Cell Killing
<Apoptotic and Mitotic Death>
• Apoptosis in Greek word : ―falling off‖
• Programmed cell death
• Occurs in normal tissues, also can be induced in some
normal tissues and in some tumors by radiation.

30. Mechanisms of Cell Killing
• For example, tadpoles lose their tails.
– To cease communicating with its neighbors
– Rounds up and detaches from its neighbors.
– Condensation of the chromatin at the nuclear membrane
and fragmentation of the nucleus.
– The cell shrinks because of cytoplasmic
condensation(crosslinking of proteins and loss of water).
– The cell separates into several membrane-bound
fragments of differing sizes : apoptotic bodies
– Double-strand breaks(DSBs) occur in the linker regions
between nucleosomes, producing DNA fragments that
are multiples of approximately 185 base pairs. 
Laddering in gels.
– Cf) necrosis causes a diffuse ―smear‖ of DNA in gels.

31. Mechanisms of Cell Killing
• Apoptosis is highly cell-type dependent.
• Hemopoietic and lymphoid cells are particularly prone to
rapid radiation-induced cell death by the apoptotic
pathway.
• Apoptosis after radiation seems commonly to be a p53-
dependent process; Bcl-2 is a suppressor or apoptosis.

32. Mechanisms of Cell Killing
• The most common form of cell
death from radiation is mitotic
death.
– Cells die attempting to divide
because of damaged
chromosomes.
– The log of the surviving
fraction
– The average number of
putative ―lethal‖ aberrations
per cell(asymmetric
exchange-type aberrations
such as rings and dicentrics) The experiment was carried out in a cell
– One-to-one correlation. line where apoptosis is not observed.

33. Mechanisms of Cell Killing
• Data such as these provide strong circumstantial
evidence to support the notion that asymmetric
exchange-type aberrations represent the principle
mechanism for radiation-induced mitotic death in
mammalian cells.

34. Mechanisms of Cell Killing
• At low doses, the two breaks may
result from the passage of a single
electron set in motion by the
absorption of a photon of x- or γ-
rays.  Linear curve
• At higher doses, may result from
two separate electrons.
 bending curve.

35. Mechanisms of Cell Killing
<Autophagic Cell Death>
• Autophagy : self-digestive process that
uses lysosomal degradation of long-
lived proteins and organelles to restore
or maintain cellular homeostasis.
• Stress-inducing condition can also
promote autophagic, or what has been
termed programmed type II, cell death.
• The combination of endoplasmic stress-
inducing agents and ionizing radiation
could enhance cell killing by inducing
autophagic cell death.

36. Mechanisms of Cell Killing
<Senescence>
• The change in the biology of an organism as it ages after its
maturity.
• Has been classified as a tumor suppressor mechanism that prevents
excessive cellular divisions in response to inappropriate growth
signals or division of cells that have accumulated DNA damage.

37. Survival Curves for Various
Mammalian Cells in Culture
• The first in vitro survival curve for mammlian cells irradiated with x-
rays.
• All mammalian cells studied to date, normal or malignant, regardless
of their species of origin, exhibit x-ray survival curves similar to
those in figure.
Initial shoulder

38. Survival Curves for Various
Mammalian Cells in Culture
• The D0 of the x-ray survival curves for most cells cultured
in vitro falls in the range of 1 to 2 Gy.
• The exceptions are cells from patients with cancer-prone
syndromes such as ataxia-telangiectasia(AT); these cells
are much more sensitive to ionizing radiations, with a D0
for x-rays of about 0.5 Gy.

39. Survival Curves for Various
Mammalian Cells in Culture
• Some researchers were skeptical that these
in vitro techniques, which involved growing
cells in petri dishes in very artificial
conditions, would ever benefit clinical
radiotherapy.
– A metaphor of ―Robinson Crusoe‖
• The in vitro culture technique measured the
reproductive integrity of cells and that there
was no reason to suppose that Robinson
Crusoe’s reproductive integrity was any
different on his desert island from what it
would have been had he remained in York.

40. Survival Curves for Various
Mammalian Cells in Culture
• In more recent years, extensive studies have been made
of the radiosensitivity of cells of human origin, both
normal and malignant, grown and irradiated in culture.
– In general, cells from a given normal tissue show a narrow range
of radiosensitivities if many hundreds of people are studied.
– By contrast, cells from human tumors show a very broad range
of D0 values.

41. Survival Curves for Various
Mammalian Cells in Culture

42. Survival Curve Shape and
Mechanisms of Cell Death
• Mammalian cells cultured in vitro vary
considerably in their sensitivity to killing by
radiation.

43. Survival Curve Shape and
Mechanisms of Cell Death
Radioresistant
Large dose-
rate effect
Radiosensitive
No dose-rate effect
Laddering
(after 10
Gy)

44. Survival Curve Shape and
Mechanisms of Cell Death
• Although asynchronous cells show this wide
range of sensitivities to radiation, mitotic
cells from all of these cell lines have
essentially the same radiosensitivity.
– In interphase, the radiosensitivity differs
because of different conformations of the
DNA.

45. Survival Curve Shape and
Mechanisms of Cell Death
• Characteristic laddering is indicative of programmed cell
death or apoptosis during which the DNA breaks up into
discrete lengths as previously described.
• Comparing Fig.A and B, it is evident that there is a close
and impressive correlation between radiosensitivity and
the importance of apoptosis.
• Increased ―laddering‖ = Increased radiosensitivity

46. Survival Curve Shape and
Mechanisms of Cell Death
• Mitotic death results (principally) from exchange-type
chromosomal aberrations; the associated cell survival
curve, therefore, is curved in a log-linear plot, with a
broad initial shoulder.

47. Oncogenes and Radioresistance
• Numerous reports have appeared in the literature that
transfection of activated oncogenes into cells cultured in
vitro increases their radioresistance, as defined by
clonogenic survival.
• It is by no means clear that oncogene expression is
directly involved in the induction of radioresistance, and
it is far less clear that oncogenes play any major role in
radioresistance in human tumors.

48. Genetic Control of Radiosensitivity
• A radiosensitive mutant can result from a mutation in a
single gene that functions as a repair or checkpoint
gene.
• In many but not all cases, their sensitivity to cell killing by
radiation has been related to their greatly reduced ability
to repair DNA DSBs.

49. Genetic Control of Radiosensitivity
<Inherited Human Syndromes
associated with sensitivity to X-rays>
• Ataxia-telangiectasia(AT)
• Seckel syndrome
• Ataxia-telangiectasia-like disorder
• Nijmegen breakage syndrome
• Fanconi’s anemia
• Homologues of RecQ-Bloom
syndrome, Wernder syndrome, and
Rothmund-Thompson syndrome

50. Intrinsic Radiosensitivity and
Cancer Stem Cells
• It has been well accepted that the radiosensitivity of cells
changes as they undergo differentiation.
– The more differentiated tumor cells, the more survival?
– No.
– In fact, cancer stem cells may be more resistant to radiation than
their more differentiated counterparts.
– Due to high intensity of free radical scavenger.
– Needs further evaluations and tests.

51. Effective Survival Curve for a
Multifraction Regimen

52. Calculations of Tumor Cell
Kill
• Problem 1
• A tumor consists of 108 clonogenic cells. The effective
dose-response curve given in daily dose fractions of 2
Gy has no shoulder and a D0 of 3 Gy. What total dose is
required to give a 90% chance of tumor cure?

54. • Problem 2
• Suppose that, in the previous example, the clonogenic
cells underwent three cell doublings during treatment.
About what total dose would be required to achieve the
same probability of tumor control?

56. • Problem 3
• During the course of radiotherapy, a tumor containing
109 cells receives 40 Gy. If the D0 is 2.2 Gy, how many
tumor cells will be left?

58. • Problem 4
• If 107 cells were irradiated according to single-hit kinetics
so that the average number or hits per cell is one, how
many cells would survive?

60. The Radiosensitivity of Mammalian Cells
Compared with Microorganisms
• It is evident that mammalian
cells are exquisitely
radiosensitive compared with
microorganisms.
• The most resistant is
Micrococcus
radiodurans, which shows no
significant cell killing even
after a dose of 1,000 Gy.
A,Mammalian cells;B,E.coli;C,E.coli B/r;D,yeast;E,phage staph
E;F. Bacillus megatherium;G,potato virus;H,M.radiodurans.

61. The Radiosensitivity of Mammalian Cells
Compared with Microorganisms
• 1. The dominant factor that accounts for this huge range
of radiosensitivities is the DNA content. Mammalian cells
are sensitive because they have a large DNA
content, which represent a large target for radiation
damage.

62. The Radiosensitivity of Mammalian Cells
Compared with Microorganisms
• 2. DNA content is not the whole story, however. E. coli
and E. coli B/r have the same DNA content but differ in
radiosensitivity because B/r has a mutant and more
efficient DNA repair system. In higher organisms, mode
of cell death -that is, apoptotic versus mitotic-also affects
radiosensitivity.

63. The Radiosensitivity of Mammalian Cells
Compared with Microorganisms
• 3. The figure explains why, if radiation is used as a
method of sterilization, doses of the order of 20,000 Gy
are necessary. Even is objects are socially clean, such
huge doses are necessary to reduce the population of
contaminating microorganisms because of their extreme
radioresistance.

64. • Thank you for listening.