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Recent advances in radiation oncology final (1)
1. Dr. Kandra Prasanth Reddy, MD
Consultant Radiation Oncologist
American Oncology Institute, LB Nagar
Recent Advances In Radiation
Oncology
2. Introduction
Radiation has been an effective tool for
treating cancer for more than 100 years
More than 60 percent of patients diagnosed
with cancer will receive radiation therapy as
part of their treatment
Radiation oncologists are cancer specialists
who manage the care of cancer patients with
radiation for either cure or palliation
Patient being treated with modern
radiation therapy equipment.
3. Overview
What is the physical and biological basis for radiation
What are the clinical applications of radiation in the
management of cancer
What is the process for treatment
Simulation
Treatment planning
Delivery of radiation
What types of radiation are available
Summary
4. What Is the Biologic Basis for
Radiation Therapy?
Radiation therapy works by damaging
the DNA of cells and destroys their
ability to reproduce
Both normal and cancer cells can be
affected by radiation, but cancer cells
have generally impaired ability to
repair this damage, leading to cell
death
All tissues have a tolerance level, or
maximum dose, beyond which
irreparable damage may occur
5. Fractionation: A Basic Radiobiologic
Principle
Fractionation, or dividing the total dose into small daily fractions
over several weeks, takes advantage of differential repair abilities
of normal and malignant tissues
Fractionation spares normal tissue through repair and
repopulation while increasing damage to tumor cells through
redistribution and reoxygenation
6. The Four R’s of Radiobiology
Four major factors are believed to affect tissue’s response to
fractionated radiation:
Repair of sublethal damage to cells between fractions caused by radiation
Repopulation or regrowth of cells between fractions
Redistribution of cells into radiosensitive phases of cell cycle
Reoxygenation of hypoxic cells to make them more sensitive to radiation
7. Clinical Uses for Radiation Therapy
Therapeutic radiation serves two major
functions
To cure cancer
Destroy tumors that have not spread
Kill residual microscopic disease left after
surgery or chemotherapy
To reduce or palliate symptoms
Shrink tumors affecting quality of life, e.g., a
lung tumor causing shortness of breath
Alleviate pain or neurologic symptoms by
reducing the size of a tumor
External beam radiation
treatments are usually scheduled
five days a week and continue for
one to ten weeks
8. Radiation Therapy in Multidisciplinary
Care
Radiation therapy plays a major role in the
management of many common cancers
either alone or as an adjuvant therapy with
surgery and chemotherapy
Sites commonly treated include breast,
prostate, lung, colorectal, pancreas, esophagus,
head and neck, brain, skin, gynecologic,
lymphomas, bladder cancers and sarcomas
Radiation is also frequently used to treat
brain and bone metastases as well as cord
compression
9. Palliative Radiation Therapy
Commonly used to relieve pain from bone cancers
~ 50 percent of patients receive total relief from their
pain
80 to 90 percent of patients will derive some relief
Other palliative uses:
Spinal cord compression
Vascular compression, e.g., superior vena cava
syndrome
Bronchial obstruction
Bleeding from gastrointestinal or gynecologic tumors
Esophageal obstruction
Radiation is effective therapy for relief
of bone pain from cancer
10. Wilhelm Roentgen
Wilhelm Roentgen discovered X-Rays in 1895
He was performing experiments on electricity, when he noted that an
energy ray was produced which passed through most objects, including
his own body
The field of Radiation Therapy - now known as Radiation Oncology -
was born shortly after this discovery
The first diagnostic x-ray was taken within 2 months of Roentgen’s
discovery
11. Marie Sklodowska Curie
While working at the Sorbonne in Paris, Marie and her husband Pierre
Curie isolated the first known radioactive elements
These elements were named Polonium and Radium
12. Emil Grubee
After noting the peeling of his hands exposed to x-rays,
medical student Emil Grubbe convinced one of his professors
to allow him to irradiate a cancer patient
The patient was suffering from advanced breast cancer
Grubbe became the World’s first Radiation Oncologist
13. Claude Regaud
• After seeing the cancer patient benefit from Grubbe’s intervention,
people began to understand the potential value of radiotherapy
• A professor at the Radium Institute in Paris, Glaude Regaud,
recognized that treatment may be better tolerated and more
effective if delivered slower and in smaller doses per day over
several weeks
• This process is known as fractionation
18. The Radiation Oncology Team
Radiation Oncologist
The doctor who prescribes and oversees the radiation therapy treatments
Medical Physicist
Ensures that treatment plans are properly tailored for each patient, and is responsible for
the calibration and accuracy of treatment equipment
Dosimetrist
Works with the radiation oncologist and medical physicist to calculate the proper dose of
radiation given to the tumor
Radiation Therapist
Administers the daily radiation under the doctor’s prescription and supervision
Radiation Oncology Nurse
Interacts with the patient and family at the time of consultation, throughout the treatment
process and during follow-up care
19. The Treatment Process
Referral
Consultation
Simulation
Treatment Planning
Quality Assurance
20. Referral
Tissue diagnosis has been
established
Referring physician reviews
potential treatment options with
patient
Treatment options may include
radiation therapy, surgery,
chemotherapy or a combination
It is important for a referring physician to discuss
all possible treatment options available to the
patient
21. Consultation
Radiation oncologist determines
whether radiation therapy is
appropriate
A treatment plan is developed
Care is coordinated with other
members of patient’s oncology team
The radiation oncologist will discuss with the
patient which type of radiation therapy
treatment is best for their type of cancer
22. Simulation
Patient is set up in treatment position on
a dedicated CT scanner
Immobilization devices may be created to
assure patient comfort and daily
reproducibility
Reference marks or “tattoos” may be
placed on patient
CT simulation images are often fused
with PET or MRI scans for treatment
planning
23. Treatment Planning
Physician outlines the target and organs
at risk
Sophisticated software is used to carefully
derive an appropriate treatment plan
Computerized algorithms enable the treatment plan
to spare as much healthy tissue as possible
Medical physicist checks the chart and dose
calculations
Radiation oncologist reviews and approves
final plan
Radiation oncologists work with medical
physicists and dosimetrists to create the
optimal treatment plan for each individualized
patient
24. Safety and Quality Assurance
Each radiation therapy treatment plan goes through many
safety checks
The medical physicist checks the calibration of the linear accelerator on
a regular basis to assure the correct dose is being delivered
The radiation oncologist, along with the dosimetrist and medical
physicist go through a rigorous multi-step QA process to be sure the
plan can be safely delivered
QA checks are done by the radiation therapist daily to ensure that each
patient is receiving the treatment that was prescribed for them
25. Delivery of Radiation Therapy
External beam radiation therapy typically
delivers radiation using a linear accelerator
Internal radiation therapy, called
brachytherapy, involves placing radioactive
sources into or near the tumor
The modern unit of radiation is the Gray (Gy),
traditionally called the rad
1Gy = 100 centigray (cGy)
1cGy = 1 rad
The type of treatment used will depend on
the location, size and type of cancer.
27. Three-Dimensional Conformal Radiation
Therapy (3-D CRT)
Uses CT, PET or MRI scans to
create a 3-D picture of the tumor
and surrounding anatomy
Improved precision, decreased
normal tissue damage
28. Intensity Modulated Radiation Therapy
(IMRT)
A highly sophisticated form of 3-D CRT
allowing radiation to be shaped more
exactly to fit the tumor
Radiation is broken into many “beamlets,” the
intensity of each can be adjusted individually
IMRT allows higher doses of radition to
be delivered to the tumor while sparing
more healthy surrounding tissue
29. Image Guidance
For patients treated with 3-D or IMRT
Physicians use frequent imaging of the
tumor, bony anatomy or implanted
fiducial markers for daily set-up
accuracy
Imaging performed using CT scans, high
quality X-rays, MRI or ultrasound
Motion of tumors can be tracked to maximize
tumor coverage and minimize dose to normal
tissues
Fiducial markers in prostate
visualized and aligned
30. Stereotactic Radiosurgery (SRS)
SRS is a specialized type of external
beam radiation that uses focused
radiation beams targeting a well-
defined tumor
SRS relies on detailed imaging, 3-D
treatment planning and complex
immobilization for precise treatment set-up
to deliver the dose with extreme accuracy
Used on the brain or spine
Typically delivered in a single treatment or
fraction
31. Stereotactic Body Radiotherapy (SBRT)
SBRT refers to stereotactic radiation
treatments in 1-5 fractions on specialized
linear accelerators
Uses sophisticated imaging, treatment
planning and immobilization techniques
Respiratory gating may be necessary for motions
management, e.g., lung tumors
SBRT is used for a number of sites: spine,
lung, liver, brain, adrenals, pancreas
Data maturing for sites such as prostate
32. Proton Beam Therapy
Protons are charged particles that deposit
most of their energy at a given depth,
minimizing risk to tissues beyond that point
Allows for highly specific targeting of tumors
located near critical structures
Increasingly available in the U.S.
Most commonly used in treatment of pediatric,
CNS and intraocular malignancies
Data maturing for use in other tumor sites
Proton Gantry
Source: Mevion
33. Types of Internal Radiation Therapy
Intracavitary implants
Radioactive sources are placed in a cavity near the tumor (breast,
cervix, uterine)
Interstitial implants
Sources placed directly into the tissue (prostate, vagina)
Intra-operative implants
Surface applicator is in direct contact with the surgical tumor bed
34. Brachytherapy
Radioactive sources are implanted into the
tumor or surrounding tissue
125I, 103Pd, 192Ir, 137Cs
Purpose is to deliver high doses of
radiation to the desired target while
minimizing the dose to surrounding normal
tissues
Radioactive seeds for a
permanent prostate implant,
an example of low-dose-rate
brachytherapy.
35. Brachytherapy Dose Rate
Low-Dose-Rate (LDR)
Radiation delivered over days and months
Prostate, breast, head and neck, and gynecologic
cancers may be treated with LDR brachytherapy
High-Dose-Rate (HDR)
High energy source delivers the dose in a matter
of minutes rather than days
Gynecologic, breast, head and neck, lung, skin
and some prostate implants may use HDR
brachytherapy
LDR prostate implant
36. Permanent vs. Temporary Implants
Permanent implants release small amounts of radiation over a period
of several months
Examples include low-dose-rate prostate implants (“seeds”)
Patients receiving permanent implants may be minimally radioactive and should avoid
close contact with children or pregnant women
Temporary implants are left in the body for several hours to several
days
Patient may require hospitalization during the implant depending on the treatment site
Examples include low-dose-rate GYN implants and high-dose-rate prostate or breast
implants
37. Intraoperative Radiation Therapy (IORT)
IORT delivers a concentrated
dose of radiation therapy to a
tumor bed during surgery
Advantages
Decrease volume of tissue in boost field
Ability to exclude part or all of dose-
limiting normal structures
Increase the effective dose
Multiple sites
Pancreas, stomach, lung, esophagus,
colorectal, sarcomas, pediatric tumors,
bladder, kidney, gyn
Several recent trials have shown efficacy
for breast cancer
38. Systemic Radiation Therapy
Radiation can also be delivered by an injection.
Metastron (89Strontium), Quadramet (153Samarium) and Xofigo
(223Radium) are radioactive isotopes absorbed primarily by
cancer cells
Used for treating bone metastases
Radioactive isotopes may be attached to an antibody targeted at
tumor cells
Zevalin, Bexxar for Lymphomas
Radioactive “beads” may be used to treat primary or metastatic
liver cancer
Y90-Microspheres
39. Radiation Therapy Basics
The delivery of external beam radiation treatments
is painless and usually scheduled five days a
week for one to ten weeks
The effects of radiation therapy are cumulative
with most significant side effects occurring near
the end of the treatment course.
Side effects usually resolve over the course of
a few weeks
There is a slight risk that radiation may cause a
secondary cancer many years after treatment,
but the risk is outweighed by the potential for
curative treatment with radiation therapy
Example of erythroderma after several
weeks of radiotherapy with moist
desquamation
Source: sarahscancerjourney.blogspot.com
40. Side Effects of Radiation Therapy
Side effects, like skin tenderness, are
generally limited to the area receiving
radiation.
Unlike chemotherapy, radiation usually
doesn’t cause hair loss or nausea.
Most side effects begin during the
second or third week of treatment.
Side effects may last for several weeks
after the final treatment.
42. Acute Toxicity
Time onset depends on cell cycling time
Mucosal reactions – 2nd week of XRT
Skin reactions – 5th week
Generally subside several weeks after completion of treatment
RTOG – acute toxicity <90 days from start of treatment (epithelial
surfaces generally heal within 20 to 40 days from stoppage of
treatment)
43. Late Toxicity
Xerostomia
Injury to serous acinar cells
May have partial recovery
Results in dental caries (in or outside of fields)
Soft tissue necrosis
Mucosal ulceration, damage to vascular connective tissue
Can result in osteo-/chondroradionecrosis
45. Late Toxicity
Fibrosis
Serious problem, total dose limiting factor
Woody skin texture – most severe
Large daily fractions increase risk
Ocular – cataracts, optic neuropathy, retinopathy
Otologic – serous otitis media (nasopharynx, SNHL (ear treatments)
46. Late Toxicity
Central Nervous System
Devastating to patients
Myelopathy (30 Gy in 25 fractions)
Electric shock from cervical spine flexion (Lhermitte sign)
Transverse myelitis (50 to 60 Gy)
Somnolence syndrome (months after therapy)
Lethargy, nausea, headache, CN palsies, ataxia
Self-limiting, transient
Brain necrosis (65 to 70 Gy) – permanent
47. Common Radiation Side Effects
Side effects during the treatment vary depending on site of the
treatment and affect the tissues in radiation field:
Breast – swelling, skin redness
Abdomen – nausea, vomiting, diarrhea
Chest – cough, shortness of breath, esophogeal
irritation
Head and neck – taste alterations, dry mouth, mucositis,
skin redness
Brain – hair loss, scalp redness
Pelvis – diarrhea, cramping, urinary frequency, vaginal
irritation
Prostate – impotence, urinary symptoms, diarrhea
Fatigue is often seen when large areas are irradiated
Modern radiation therapy techniques have decreased these
side effects significantly
Unlike the systemic side effects from
chemotherapy, radiation therapy
usually only impacts the area that
received radiation
48. Is Radiation Therapy Safe?
Many advances have been made in the field
to ensure it remains safe and effective.
Multiple healthcare professionals develop
and review the treatment plan to ensure that
the target area is receiving the dose of
radiation needed.
The treatment plan and equipment are
constantly checked to ensure proper
treatment is being given.
59. Metastatic Ca. Ovary (SBRT)
SBRT to Single Metastatic Lesion In Brain (30 Gy/5#)
60. Summary
Radiation therapy is a well established modality for the
treatment of numerous malignancies
Radiation oncologists are specialists trained to treat
cancer with a variety of forms of radiation
Treatment delivery is safe, quick and painless
An overview of topics included in the presentation.
Radiation therapy damages the DNA of cells – normal cancer cells are able to repair themselves but cancer cells have an impaired ability to repair the damage, unlike healthy cells.
Radiation therapy has multiple sources to be used for delivery.
Most radiation therapy treatments are delivered using photons which are either delivered with Gamma Rays (such as radioisotopes used in brachytherapy) and X-rays (generated by a linear accelerator)
Additional sources include particle beams such as protons, neutrons and electrons
Between each treatment, healthy cells are able to repair themselves and cancer cells slowly break down. As the cell life continues, the repeated treatments continue to kill the cancer cells as they become sensitive to the radiation.
Radiation therapy typically has two primary uses:
To cure cancer by destroying tumors that have not spread or to kill residual disease left after chemotherapy or surgery
To reduce or palliate symptoms by shrinking tumors that affect quality of life or alleviate pain or neurologic symptoms by reducing the tumor size
Radiation therapy treatment plans often include adjuvant therapies, such as surgery and/or chemotherapy, in order to to enhance its effectiveness and reduce the chance of the tumor recurring.
Palliative radiation therapy is commonly used to relieve pain from bone cancers. It has been shown that 80 to 90 percent of patients derive some relief from this.
Additional palliative uses include spinal cord compression, vascular compression, bronchial or esophageal obstruction or bleeding from GI for gyn tumors.
The radiation therapy treatment team works closely to ensure that patients are receiving safe, quality treatment.
Because the referring physician kicks off the treatment process, it is extremely important for the referring physician to have a basic understanding of potential treatment options available.
Once a patient has been diagnosed with a cancer, it is important for their referring physician to discuss all of the possible treatment options available to the patient.
A radiation oncologist will discuss with the patient if radiation is the appropriate treatment for their cancer. Care is then coordinated with other members of the patient’s oncology team, which could include a medical oncologist or surgical oncologist. It is important for the referring physician to be kept in the loop about the treatment plan.
Simulation is an important step in the beginning of the treatment process. The patient is set up for treatment so that immobilization devices can be created, reference marks may be placed on the patient. Measurements and additional scans may be taken at this time.
The radiation oncologist works very closely with the medical physicist and dosimetrist to create the optimal individualized plan for each patient.
The radiation oncologist uses consensus atlases to outline the target and avoidance structures and then uses sophisticated software to create an appropriate treatment plan. Using nationally approved constraints, the treatment team creates a plan that will spare as much healthy tissue as possible.
Safety is very important in the delivery of radiation therapy and each radiation therapy treatment team goes through many checks and balances to ensure that patients are receiving the correct dose to the correct area. The radiation oncologist works with the dosimetrist and medial physicist to go through rigourous quality assurance processes to be sure that the radiation therapy plan can be safely delivered.
In addition, each facility works follows state and federal regulations to help with their checks and balances.
Radiation therapy is delivered in two ways, External Beam Radiation Therapy and Internal Radiation Therapy. The absorbed dose is the quantity of radiation absorbed per unit mass of absorbing material. The RAD, or Radiation absorbed dose, is the traditional basic unit. The modern unit is the Gray (Gy), and is defined as 1 joule absorbed/kg. A dose may be prescribed as a Gy or cGy (centigray).
Two dimensional radiation therapy uses X-rays to localize tumor. The other types of External Beam Radiation Therapy are much more
There are specially designed linear accelerators with built in imaging capabilities that allow for simultaneous imaging to assure precise radiation delivery.
Motions of tumors can be tracked to ensure that the maximum dose is delivered to the tumor while minimizing dose to the normal tissues.
Stereotactic Radiotherapy, commonly referred to as SRS, was developed in 1949 to treat small targets in the brain that could not be surgically removed. It uses a 3-D coordinate system device and fiducial markers, along with specialized immobilization to deliver very precise treatment and is typically delivered in a single fraction.
SRS is now more commonly referred to as stereotactic body radiotherapy or SBRT and is used to treat a number of sites in addition to the brain including spine, lung, liver, adrenal, pancreas and prostate)
There are several external beam machines used to deliver SBRT such as linear accelerators, Cyberknife and Gamma Knife.
SBRT is typically delivered in a few high-dose fractions.
Proton therapy is increasingly becoming available in the United States with more centers opening each year. Protons have historically been used to treat CNS tumors and pediatric cancers.
Low-dose-rate brachytherapy is delivered over the course of 48 to 120 hours and is typically used to treat prostate, breast, head and neck and gyn cancers. High-dose-rate brachytherapy is delivered in minutes rather than days and is typically used to treat certain types of gyn, breast, head and neck, lung and skin cancers. Some prostate cancers may be treated with high-dose-rate brachytherapy.
Brachytherapy is delivered through permanent or temporary implants depending on the cancer and location. Permanent implants remain in the patient and eventually lose their radioactivity. An example of this is prostate seed implants. Temporary implants may require hospitalization and are left in the body for several hours to days and are then removed. An example of this is high-dose-rate breast implants.
Systemic radiation therapy uses radiopharmaceuticals, given by injection or intravenously, that collect where the cancer is and deliver their radiation to kill the cancer cells. Some of the radioactive isotopes used are listed on this slide.
While the delivery of external beam radiation therapy is painless, patients may experience side effects throughout their treatments and at the end. Side effects typically resolve within a few weeks of treatment completion. Side effects can be anything from skin redness in the are treated to GI discomfort.
There is a risk of secondary cancers from treatment, but the benefits from the potential cure usually far outweighs the risk.
Modern radiation therapy techniques have decreased these side effects significantly
Radiation therapy is safe and effective and should be considered by patients and referring physicians as treatment for numerous cancers.
