. 2021 Jun 16;48(13):4236–4245. doi: 10.1007/s00259-021-05461-6

Table 1.

Opportunities and challenges of long axial field of view PET scanners

New opportunities	Challenges
Improved image quality and high signal to noise
• Decrease population sampling size which will lead to faster translation of new/existing radiotracers • No need for post-filtering • Reconstruct images at smaller voxel size • Measure/correct motion using PET data • Increase specificity/sensitivity • Increase reproducibility • Detect low-grade uptake • Detect disease at earlier stages	• Amend standardisation values/harmonisation • Substantially non-uniform sensitivity along the axial field of view
Short imaging protocols
• High patient throughput • Avoid anaesthesia in children • Scan ICU patients • Reduce motion artefacts • Reduce patient inconvenience and consequently increase compliance • Increase screening high-risk but otherwise healthy individuals	• More hot uptake rooms needed
Imaging with lower doses (as many more otherwise lost counts can be measured)
• Imaging radiosensitive populations (paediatrics, pregnant women) • Imaging larger populations which will lead to faster translation of new/existing radiotracers and better understanding of health/disease • Less affected by radiophobia, which will help replace other diagnostic procedures • Use radiotracers with poor labelling efficiency or low positron emission branching ratio • Wider acceptance for use in clinical trials • Imaging the same patient more sessions, which will lead to frequent/accurate therapy evaluation	• Still requires CT for attenuation correction, which poses a significant limit to dose reduction (unless CT scan is avoided.) • Intrinsic ¹⁷⁶Lutetium radiation adds background noise
Imaging kinetics with greater temporal range
• Imaging slower biological processes (e.g. radionuclide therapy and immunotherapy) • Imaging faster biological process due to higher temporal sampling • Imaging biological processes for much longer half-lives of the radiotracer • Derive accurate input function from short frames • Extract more relevant/valuable information from one scan • Increase specificity/sensitivity • Increase reproducibility • Identify input function delay in different organs • Enabling imaging more than one tracer simultaneously	• Require accurate motion correction • Require input function • Require metabolites • Require appropriate kinetic model due to kinetic heterogeneity • Slow computational times for reconstruction, data corrections and kinetic modelling
Imaging longer axial FOV
• Imaging multiple regions at the body and investigate potential correlations • Biodistribution of newly developed (potentially radiolabelled) drugs • Improve accuracy of dose estimation for radionuclide or other radiomolecular therapies • Measure input function from aortas	• Requires checks of structural limits of the floor • Expensive (when compared to conventional PET) • May require bigger space • Makes difficult to withdraw blood samples or other interventions during the scan • Claustrophobic patients will be harder to scan • Increases environmental footprint • Adaptation of current QA procedures with longer phantoms which can be more difficult and time-consuming to handle • Data storage and networking infrastructure • If it replaces several conventional scanners or breaks, no other scanners available

New opportunities

Challenges

Improved image quality and high signal to noise

• Decrease population sampling size which will lead to faster translation of new/existing radiotracers

• No need for post-filtering

• Reconstruct images at smaller voxel size

• Measure/correct motion using PET data

• Increase specificity/sensitivity

• Increase reproducibility

• Detect low-grade uptake

• Detect disease at earlier stages

• Amend standardisation values/harmonisation

• Substantially non-uniform sensitivity along the axial field of view

Short imaging protocols

• High patient throughput

• Avoid anaesthesia in children

• Scan ICU patients

• Reduce motion artefacts

• Reduce patient inconvenience and consequently increase compliance

• Increase screening high-risk but otherwise healthy individuals

• More hot uptake rooms needed

Imaging with lower doses (as many more otherwise lost counts can be measured)

• Imaging radiosensitive populations (paediatrics, pregnant women)

• Imaging larger populations which will lead to faster translation of new/existing radiotracers and better understanding of health/disease

• Less affected by radiophobia, which will help replace other diagnostic procedures

• Use radiotracers with poor labelling efficiency or low positron emission branching ratio

• Wider acceptance for use in clinical trials

• Imaging the same patient more sessions, which will lead to frequent/accurate therapy evaluation

• Still requires CT for attenuation correction, which poses a significant limit to dose reduction (unless CT scan is avoided.)

• Intrinsic ¹⁷⁶Lutetium radiation adds background noise

Imaging kinetics with greater temporal range

• Imaging slower biological processes (e.g. radionuclide therapy and immunotherapy)

• Imaging faster biological process due to higher temporal sampling

• Imaging biological processes for much longer half-lives of the radiotracer

• Derive accurate input function from short frames

• Extract more relevant/valuable information from one scan

• Increase specificity/sensitivity

• Increase reproducibility

• Identify input function delay in different organs

• Enabling imaging more than one tracer simultaneously

• Require accurate motion correction

• Require input function

• Require metabolites

• Require appropriate kinetic model due to kinetic heterogeneity

• Slow computational times for reconstruction, data corrections and kinetic modelling

Imaging longer axial FOV

• Imaging multiple regions at the body and investigate potential correlations

• Biodistribution of newly developed (potentially radiolabelled) drugs

• Improve accuracy of dose estimation for radionuclide or other radiomolecular therapies

• Measure input function from aortas

• Requires checks of structural limits of the floor

• Expensive (when compared to conventional PET)

• May require bigger space

• Makes difficult to withdraw blood samples or other interventions during the scan

• Claustrophobic patients will be harder to scan

• Increases environmental footprint

• Adaptation of current QA procedures with longer phantoms which can be more difficult and time-consuming to handle

• Data storage and networking infrastructure

• If it replaces several conventional scanners or breaks, no other scanners available