Adaptive Radiotherapy

Question 1

Overall benefits of ART

Answer 1

• Accounts for temporal changes in anatomy and changes in tumour biology/function
• Accounts for organ motion
• Accounts for variation in patient position

Question 2

What is ART?

Answer 2

• Adaptive radiotherapy
• Adaptive radiotherapy is defined as changing
  the radiation treatment plan delivered to a
  patient during a course of radiotherapy to
  account for:

u Temporal changes in anatomy (e.g. tumor
shrinkage, weight loss or internal motion)

u Changes in tumor biology/function (e.g. hypoxia)

Question 3

Advantages of IGRT

Answer 3

• Can lead to reduced target margin
• May decrease dose to surrounding OAR
• Provides rich 3D information which can be used as the basis for adaptive planning intervention - modification of the initial plan

Question 4

IGRT Role in ART

Answer 4

• Images taken just prior to treatment delivery
• Assess changes in patient position relative to treatment plan
• Adapting positioning to account for variation —> increased treatment precision

Question 5

Clinical Examples of IGRT

Answer 5

• 4DCT capabilities (Elekta Symmetry)
• Patient Motion Detection (iGuide, SGRT)
• Detection of Correct Floor Rotation (Exactrac)
• Video-based systems (Varian RPM)
• Ultrasound (Clarity Autoscan)
• RF Tracking (Calypso)
• MRI

Question 6

Limitations of IGRT

Answer 6

Image guidance in isolation can not correct for non-rigid changes

Question 7

Timepoints of ART Application

Answer 7

Offline (between fractions)
* Most common form of AR
* Continue treating the patient while the plan is being re-planned and assessed

Online (immediately before a fraction)
* Plan is adapted prior to treatment - XRT phase is not continued until plan is assessed and complete

Real-time (during a fraction)
* Dose calculation during real time
* Some technology can locate the target and treat simultaneously

It can also be a combination of online and offline

Question 8

Real-time workflow

Answer 8

Technology to locate the target during real-time
RF waves: Calypso, RayPilot
Dose calculation during real-time
Technology to hit the target in real-time

Question 9

Limitations with Current Bladder XRT

Answer 9

Organ Motion
* Size, shape and position can significantly change both intra and interfractionally
* Leads to generous margin (2-3cm) patients experience side effects which potentially can be avoided
* Need to decrease prescriptive dose to account for this (dose escalation is often related to poor treatment outcomes)

Question 10

Current Dosing for Bladder ART

Answer 10

• General prescribed dose: 50-66Gy (relatively low in comparison to other sites)
• Could be related to poor outcomes with bladder cancer
• Retrospective studies suggest significant improvement in outcome with dose escalation (may be possible with ART)

Question 11

Bladder: Online ART Workflow

Answer 11

Step 1: Daily pre-treatment CBCT
Step 2: Plan of the Day (most popular method currently used clinically)

Question 12

Bladder: Offline ART Workflow

Answer 12

• Adaptive PTV delineated based on information from the first 5# CBCT’s.
• Utilisation of patient specific margins

Question 13

Limitations with Current Prostate XRT

Answer 13

• Size, shape and position is dependent on bordering organs (rectum, bladder)
• Can lead to under/overdosing of prostate, bladder, rectum → side effects

Question 14

Prostate: Offline ART

Answer 14

• Delivered dose and variation of OARS is accounted for in the planning objective function.
• Dose distribution accomplished in the adaptive plan is used for the remaining treatment.
• Optimiser increases/reduces dose in sections of target volume, dependent of dose already delivered in treatment.

Question 15

Prostate: Online ART

Answer 15

• kV intrafraction monitoring
• Real time localisation method
• Can be used to track gold seeds image is taken approx. every 30 degrees and couch can be shifted to account for intrafraction motion.

Question 16

Prosate: Real-Time ART

Answer 16

• Together, KIM and MLC enable IGART using a standard LA without additional equipment.
• Current onboard CBCT imaging is suboptimal for online guidance of prostate

Question 17

Limitations with Current Lung XRT

Answer 17

• Prognosis for NSCLC is poor (<50% 5 year survival)
• Dose escalation studies show promising results – increased loco-regional control and improved survival.
• Routine dose escalation restricted by surrounding dose limiting structures/side effects.
• Respiratory motion - very patient dependent and can vary from 1cm to 2cm.

Question 18

Benefit of ART in Lung XRT

Answer 18

• Improved tumour delineation and margin selection
• Adaption for treatment plan due to biological and function response
• Allows for dose escalation, dose maintenance and normal tissue sparing.

Question 19

Briefly explain ‘Gating’

Answer 19

Imaging and treatment devices are periodically turned on and off, in phase with the patient’s breathing pattern, in order to restrict the range of positions of the tumour and internal anatomy.

Question 20

What are two primary methods of ‘Gated’ XRT

Answer 20

• Breath Hold
• Free Breath (with real-time monitoring)

Question 21

What is the benefit of ‘breath control’ techniques?

Answer 21

Can be used to suspend breathing at any predetermined position along the normal breathing cycle

Question 22

Provide the steps involved in the application of ABC in treatment

Answer 22

• Patient breathes normally
• Operator activates system →machine will be shut down at specified volume
• Patient proceeds with specified lung volume
• Valve is inflated with an air compressor for a predefined duration of time.
• Breath hold duration is patient dependent, typically 15-30 seconds.
• Radiation delivered during breath hold.

Question 23

Briefly explain ‘tumour tracking’ in Lung XRT

Answer 23

Dynamically shifting dose in space as to follow the tumours changing position during free breathing.

Question 24

Provide examples of Biological and Functional Imaging used for Lung Patients

Answer 24

• PET Imaging
• SPECT Imaging
• Ventilation Imaging
• Perfusion Imaging

Question 25

Application of PET Imaging in Lung XRT

Answer 25

• FDG-PET is increasingly used to monitor tumour response in NSCLC patients.
• May allow prediction of tumour response and or radiation induced lung toxicity.
• Early identification has potential to reduce side effects and costs of ineffective or toxic treatment

Question 26

Application of SPECT Imaging in Lung XRT

Answer 26

• Single Photon Emission Computed Tomography
• Assess lung function.
• Can be used to design and plan in accordance with tissue variation.

Question 27

What is Ventilation Imaging?

Answer 27

• Assessing the movement of air between the atmosphere and alveoli and the distribution of air within the lungs to maintain appropriate concentrations of oxygen and carbon dioxide in the blood.
• Can be used before, during and after treatment

Question 28

What is Perfusion Imaging?

Answer 28

• The movement of blood through the pulmonary capillaries
• Can be used before, during and after treatment
• May be able to adapt the plan and ‘boost’ areas of active tumour

Question 29

Limitations with Current H/N XRT

Answer 29

• Can undergo considerable anatomic and tumour change.
• Weight change
• Change in size and shape of tumour and nodal disease.
• Change in OAR size and shape.
• Post op changes (oedema)

Question 30

Effect of Changes in Anatomy in H/N XRT

Answer 30

Dose distribution:
* Altered dosimetry
* Altered dose gradient
* Inadequate coverage

Clinical impact:
* Loco-regional recurrence
* OAR’s exceeding tolerance dose → increased severity of side effects

Question 31

Potential methods of Application of ART to account for Positioning Variation

Answer 31

Method One:
* ART aims to customise treatment plan to patient specific variation by evaluating and characterising systematic and random patient specific variations through feedback

Method Two:
* Quantify errors in setup error → re-optimise plan to account for varied dose distribution to the target across the delivered fractions → alter dose distribution for following fractions.

Question 32

What is Deformable Image Registration?

Answer 32

• Finding geometric correspondences between imaging data sets (2D/3D/4D) that differ in time, space, modality
• Propagates planning contours to daily images (reduced time for re-contouring)
• Dose deformation and accumulation (use of deformable vector field to propagate dose distribution)

Question 33

Benefits of MRI Linac in ART

Answer 33

• Hybrid linac combined with MRI
• 1.5T linac can be used for image guidance in multiple sites providing diagnostic quality images during treatment delivery
• Allows for accurate image-guided daily ART
• Allows for daily fast adaptive replanning and gated or tracked treatment
• Functional imaging may allow for adaptive focal boosting and personalised inhomogenous target dosage based on response

Question 34

MR Linac - Adapt to Position

Answer 34

• Allows for plan adaptation based on the online patient position
• Based on rigid registration → isocenter position in the reference data is updated
• Re-treatment plan recalculated or re optimised to reproduce or improve the target coverage
• No contours need to be edited as original contours will be used for adapted plan

Question 35

MR Linac - Adapt to Shape

Answer 35

• Allows for plan adaptation based on new patient anatomy and plan is optimised on daily MRI and adapted contours
• Pre-treatment contours automatically propagated by deformable registration onto the online planning MRI (if necessary, contours can be edited by RO)
• Plan is recalculated or re optimised on online planning MRI and adjusted contours

Question 36

Adapt to Position vs Adapt to Shape

Answer 36

• ATP plan adaptations are faster than ATS
• ATP can lack target coverage
• Total treatment time ranges from 30 to 85 minutes (most completed within 60 minutes)

Question 37

Brief explanation of Radixact Synchrony

Answer 37

• Updated form of Tomotherapy
• Integrated intrafraction motion management based on the Synchrony
• Used software to predict motion based on implanted fiducials or tumour itself (using imaging information to actively track and correct for movement)

Question 38

Overall Limitations of ART

Answer 38

• Time and resource intensive (major barrier to routine clinical adoption)
• Financial burden on radiation therapy department
• Determination of appropriate patient selection
• Determination of optimal number of replans
• Lack of consensus guidelines across locations
• Extensive re-contouring may be required → more automation may be required
• Determination of appropriate POD creation
• Accounting for intra-fraction motion
• Imaging distortions in CT and MRI modalities
• Optimal method of image registration not yet decided - rigid vs deformable

Question 39

Why do we need Lung ART

Answer 39

Tumour changes:
- decreases in size
- increases in size
- can be difficult to determine due to atelectasis or unhealthy lung
- variation in size and shape
- surrounding tissue change

Question 40

What happens to parotid glands during RT

Answer 40

Shifts medically
Significant decrease in size

Question 41

What does the magnitude of dosimetric impact depend on in ART

Answer 41

Location of high dose target volumes
Proximity of OARs to high dose region
Dose gradient

Question 42

Head and neck trials

Answer 42

ARTFORCE
MiADAPT
MRADAPTOR

Deescalation of dose based on functional imaging assessments

Question 43

Biological adaption for H+N

Answer 43

Would allow modification of treatment based on
changes in tumor resistance factors and normal tissue
function

u Allow adaptation based on assessment of early
response

u Define volumes that would benefit from dose
escalation

u Utilisation of MRI Linac

Question 44

Use of ART in H+N

Answer 44

Positioning errors
Anatomical change
Biological response (only in research)

Question 45

Why do we do functional imaging for lung patients

Answer 45

• early identification of non-responding patients
• patients at high risk for radiation induced lung toxicity -> reduce side effects
• FDG uptake highlights this
• highlights functioning lung: can reduce dose to this region

Question 46

What should tumour tracking be able to do to be integrated clinically?

Answer 46

Identify tumour position in real time

Anticipate tumour motion to allow for time delays in beam response

Reposition the beam

Adapt dosimetry to allow for changing lung volume and critical structure locations during the breathing cycle