beam directed radiotherapy - methods and principles

Beam Directed Radiothe

rapy – Principle

s and practice

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Definition

Exact Calculations Beam Directing devices

Advance Planning

Beam directed radiotherapyBeam directed radiotherapy

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Need for Beam directionHomogenousHomogenous Tumor Dose LowLow normal tissue dose

Best therapeutic ratio

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

StepsPositioning

Immobilization

Localization

Field SelectionDose distribution

Calculations

Verification

Execution

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Positioning• Patient positioning is the most vital

and often the most NEGLECTEDNEGLECTED part of beam direction:

• Good patient position is ALWAYS:– Stable.– Comfortable.– Minimizes movements.– Reproducible.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Examples

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Standard Positions

• MC used body position.• Also most comfortable.• Best and quickest for

setup.• Minimizes errors due to

miscommunication.

• Best for treating posterior structures like spine

• In some obese patients setup improved as the back is flat and less mobile.

Supine

Prone

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Positioning aids• Help to maintain patients in non

standard positions.• These positions necessary to

maximize therapeutic ratio.• Accessories allow manipulation of

the non rigid human body to allow a comfortable, reproducible and stable position.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Positioning aids…

Pituitary Board

Prone Support

3 way support

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Breast Boards• Disadvantages:

– Possibility of skin reactions in the infra mammary folds

– Access to CT scanners hampered

• Solutions:– Thermoplastic

brassieres.– Breast rings.– Prone treatment

support.

• Allow comfortable arm up support ► brings arms out of the way of lateral beams.

• Positions patient so that the breast / sternum is horizontal ► avoiding angulation of the collimator.

• Pulls breast down into a better position by the pull of gravity.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Breast boards…

Modern Breast Board

Indexed Arm supports

Indexed wrist support

Head rest

Carbon fiber tilt board

Wedge to prevent sliding

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Arm Support

• Also known as the T bar.

• Allows the arm to be positioned laterally when treating the thorax using lateral beams.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Belly boards & leg immobilizer`

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Mould making

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Mould making : Contd..

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Mould making : Contd..

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Thermoplastics• Thermoplastics are

long polymers with few cross links.

• They also possess a “plastic memory” - tendency to revert to normal flat shape when reheated

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Thermoplastics : Principle

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Foam systems• Made of polyurethane• Advantages:

– Ability to cut treatment portals into foam.

– Mark treatment fields on the foam.

– Rigid and holds shape.

• Disadvantages:– Chance of spillage– Environmental hazard

during disposal

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Vacuum bags

• Consist of polystyrene beads that are locked in position with vacuum.

• Can be reused.• However like former immobilization not perfect.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Bite Blocks• A simple yet elegant

design to immobilize the head.

• A dental impression mouthpiece used.

• The impression is attached to the base plate and is indexed.

• Head position recorded with 3 numbers.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

SRS devices• Sterotactic frames.• Gill Thomas

Cosman System.• TALON® Systems –

NOMOS corp.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Localization• The target volume and critical normal

tissues are delineated with respect with respect toto patient’s external surface contour.

• What to localize?– Tumor– Organ

• Methods?– Clinical examination– Imaging

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Why Localize?• Irradiate the tumor and spare the

normal tissue.• Allow calculations and beam

balancing.• Define radiation portals.• Use the beam directing devices.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Clinical localization• Advantages:

– Available everywhere. – Cheapest and quickest(?).– Needs little additional equipment.

• Disadvantages:– Error prone in the wrong hands.– Accessible areas required.– Volumetric data not easily obtained.

• Clinical localization is mandatory despite advanced imaging – need to know what to image!

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Imaging Localization• Imaging:

– X-rays:• Plain • Contrast Studies

– CT scans– MRI scans – USG scans– PET scan– Fusion imaging

• Type of study selected depends on:– Precision desired.– Cost considerations– Time considerations– Labour

considerations

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

X rays• The most common and

cheapest modality available.

• However 2-D data acquired only.

• Orthogonal films can be used with appropriate contrast enhancement for localization in 3 dimensions.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Estimation of depth• From data gained by localization

studies:– CT / MRI – Accurate data– Lateral height method– Tube shift method

• Depth estimation necessary for:– Calculations– Selection of beam energy

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Lateral height method

d

d

H1 + H2

2d =

H1H2

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Tube shift method• Image shift and tube shift are

interrelated WHEN the tube to target distance remains constant.

• Goal: To obtain a graph of different object heights against the tube shift.

• Serial measurements of image shift measured (for same tube to film distance) while varying the height of the markers above the table.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Tube shift principles

Marker

d2

y

f

S

Tumor

x1

x2

d1

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Calculation

d1

f

yyd2

x1

x2

x1

S=

d1

f – d1

S

x2

S=

d2

f – d2

yy = d2 – d1

= fx2 + S

x2 -x1 + S

x1

TumorMarker

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

CT scans• Provides electron density

data which can be directly used by the TPS.

• Volumetric reconstruction possible.

• Good image resolution - better where bony anatomy is to be evaluated.

• The image is a gray scale representation of the CT numbers – related to the attenuation coefficients.

• Hounsfield units = (μtissue – μwater) x 1000/ (μwater)

253 265 235

125 125 112

56 450 156

135 158 247

269 300 65

36 123 598

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

CT scan perquisites• Flat table top • Large diameter scan aperture

(≥ 70 cm).• Positioning, leveling and

immobilization done in the treatment position.

• Adequate internal contrast – external landmarks to be delineated too.

• Preferably images to be transferred electronically to preserve electron density data.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

MRI scans• Advantages:

– Imaging in multiple planes without formatting.– Greater tissue contrast – essential for proper

target delineation in brain and head and neck– No ionizing radiation involved.

• Disadvantages:– Lower spatial resolution– Longer scan times– Inability to image calcification or bones.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Fusion Imaging• Includes PET – CT

imaging and Fusion MRI.

• Allows “biological modulation” of radiation therapy.

• Technology still in it’s infancy – (?) The future of radiotherapy.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Patient Contouring• Contour is the representation of

external body outline.• Methods:

– Plaster of Paris– Lead wire– Thermoplastic contouring material– Flurographic method– CT/MRI

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Contour Plotter

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Radiation Field

• Types:– Geometrical: Area DEFINED by the light beam at any

given depth as projected from the point of origin of the beam.

– Physical: Area encompassed by the 50% isodose curve at the isocenter. In LINACs often defined at the 80% isodose.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Single Field• Criteria for

acceptability:1. Dose distribution to

be uniform (±5%)2. Maximum dose to

tissues in beam ≤ 110%.

3. Critical structures don’t receive dose exceeding their normal tolerance.

• Situations used:– Skin tumors– CSI– Supraclavicular

region– Palliative treatments

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

2 Field techniques• Can be :

– Parallel opposed– Angled

• Perpendicular• Oblique

– Wedged pair

• Advantages:– Simplicity– Reproducibility– Less chance of

geometrical miss– Homogenous dose

• Dose homogeneity depends on:– Patient thickness– Beam energy– Beam “flatness”

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Multiple fields• Used to obtain a “conformal” dose

distribution in the modern radiotherapy techniques.

• Disadvantages:– Integral dose increases– Certain beam angles are prohibited due to

proximity of critical structures.– Setup accuracy better with parallel

opposed arrangement.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Dose distribution analysis• Done manually or in the TPS.• Manual distribution gives a hands on

idea of what to expect with dose distributions.

• Inefficient and time consuming.• Pros:

– Cheap– Universally available– Adequate for most clinical situations.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Calculations• Techniques:

– SSD technique (PDD method)– SAD technique– Clarkson’s technique– Computerized

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Prescription• Mandatory statements:

– Dose to be delivered.– Number of fractions– Number of fractions per week

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

SSD technique• PDD is the ratio of

the absorbed dose at any point at depth d to that at a reference depth d0.

• D0 is the position of the peak absorbed dose.

• Dmax is the peak absorbed dose at the central axis.

Total Tumor dose

Number of fieldsx

Number of #s

=T

Incident dose =

T x 100

PDD

Time =ID

Output

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

SAD Technique• Uses doses normalized at isocenter for

calculation.• In this technique the impact of setup

variations is minimized.• Dose homogeneity is better with the

SAD technique.• Setup is easier but manual planning

not possible / difficult.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

SAD calculations

Total Tumor dose

Number of fieldsx

Number of #s

=T

Incident dose =

T x 100

TMR/TARTime =

IDOutput

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

TAR vs. SSD• TAR = Tissue Air

Ratio• TAR introduced by

Jones for rotation therapy.

• Allows calculation of dose at isocenter WITHOUT correcting for varying SSDs.

• TAR is the ratio of dose at a point in the phantom to the dose in free space at the same point (Dq /D0)

Dq D0

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

TAR• TAR removes the influence of SSD as it

is a ratio of two doses at the SAME point.

• However like PDD the TAR also varies with:– Energy– Depth– Field Size– Field Shape

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Verification• Can be done using:

– Portal Films– Electronic Portal images– Cone Beam CT mounted on treatment

machines (IGRT).• Portal Films:

– Cheapest.– Legal necessity(?)– But have several disadvantages.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Port film disadvantages• Factors leading to poor image

contrast:– High beam energy (> 10 MV)– Large source size ( Cobalt)– Large patient thickness (> 20 cm)

• Slow acquisition times.• Image enhancement not possible.• Storage problems.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Electronic Portal Imaging• Video based EPIDS• Fiber optic systems• Matrix liquid ion

chambers• Solid state detectors• Amorphous Si

technology*

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Electronic Portal Imaging

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Advantages of EPIDs• Allow real time verification

of patient setup.• Acquisition times short.• Multiple images possible.• Reasonable image quality.• Software assisted image

enhancement.• Online corrections

possible.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Disadvantages of EPIDs• Cost of equipment.• Added service and software update

requirements.• Fragility of the equipment – Si matrix

deteriorates with time and exposure.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Cone Beam CT• Incorporates a

special CT scanner on the LINAC.

• Useful to obtain 3 D real time images of the patient.

• Can use kilovoltage or megavoltage CT

• Allows IGRT.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Beam direction devicesThe main beam direction devices are:

– Collimators– Front pointer / SSD indicator– Back Pointer– Pin and arc– Isocentric mounting– Lasers

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Collimators• Collimators provide beams of desired

shape and size.• Types:

– Fixed / Master collimator.– Movable / Treatment collimator.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Fixed Collimators• Protects the patient from bulk of the

radiation.• Dictates the maximum field size for

the machine.• Maximum beam size is when exposure

at periphery is 50% of that of the center.

• In megavoltage radiotherapy beam angle used is 20°.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Master Collimator : Design

20°

• In megavoltage x ray machines beam energy is maximum in forward direction.

20°

• Beam energy is equal in telecurie sources so primary collimators are spherical.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Movable Collimators• Define the required field size and

shape.• Placed below the master collimators

results in trimming of the penumbra.• Types:

– Applicators– Jaws / Movable diaphragms

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Applicators: Design

Metal Plate with hole

Lead Sheet

Box

Plastic Cap

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Applicators • Advantages:

– Indicate size and shape of beam.

– Distance maintained.– Direction shown.– Plastic ends allow

compression.– Compression allows

immobilization.– Penumbra

minimized.

• Disadvantages:– Useful for low

energy only.– Separate sizes and

shapes required.– Costly.– Shapes may change

due frequent handling.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Jaws• Handling of heavy weight

not required.• Skin sparing effect

retained.• Jaws moved mechanically

– accurately.

Jaw border lies along the line radiating from

focal spot

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Jaws: Disadvantages

Disadvantages RemedySize and shape of field remain unknown

Light beam shining through the jaws

Patient to source distance unknown

SSD indicator used.

Compression not possible

A Perspex box may be applied to the head

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Front & Back Pointers

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Front Pointer/ SSD indicator• Detachable device to measure the SSD

and align the beam axis.• Designed so that it may be swung out

of the beam path during treatment.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Back Pointer• The pointer can be moved in the sleeve.• A nipple is used to allow compression.• The arrow lies along the central ray.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Limitations• Requires skin marks – inherently

unreliable.• Back pointer is unreliable when

compression is desired.• Both front and back points must be

accessible.• Accurate localization of tumor center

is mandatory.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Pin & Arc

Pin

Arc

Bubble

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Pin & Arc: Principle

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Pin & Arc : Methodd

D

d DD

This is the isocenter

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Advantages of Pin & Arc• Allows Isocentric treatment of

– Deep tumors.– Eccentric tumors.

• Can be used with compression e.g. in treating deep seated tumors.

• Can be used for manual verification of Isocentric placement of machines

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Isocentric Mounting• First used by Flanders and Newberg of

Hammersmith Hospital for early linear accelerators.

• The axis of rotation of the three structures:– Gantry– Collimator– Couch

coincide at a point known as the Isocenter.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Principle of Isocentric mounting

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Why Isocentric Mounting?• Enhances accuracy.• Allows faster setup and is more

accurate than older non isocentrically mounted machines.

• Makes setup transfer easy from the simulator to the treatment machine.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Lasers• LASER = Light Amplification Of

stimulated Emission Of Radiation• Typically 3 pairs are provided with

the machine and intersect at the isocenter.

• Also define:– Beam Entry– Beam Exit

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

Lasers• Other uses:

– Checking the isocenter– Reproducing the setup on the simulator at

the treatment couch.

• Fallacies:– Accurate setup depends on proper

alignment of the lasers themselves– Lasers known to move frequent

adjustments needed.

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

How to setup with LASER

2. Align the fiduciary marks with the laser

system

3. Move the couch by to bring the

planned isocenter to the machine

isocenter

1. Note the coordinates of the isocenter

4. Verify the Setup

5. Treat

Moderator: Dr F D Patel , Department of Radiotherapy, PGIMER

ConclusionTeam Work Precision

Quality Assurance

Thank You