EXPLORER.ucdavis.edu

EXPLORER:

A Total-Body PET Scanner

for Biomedical Research

EXPLORER

Approach the Limits of PET Sensitivity

EXtreme Performance LOng REsearch scanneR

History of the

“Long Scanner” Idea

Terry Jones

1990

Karp et al, 3D imaging characteristics of the HEAD

PENN-PET scanner. J. Nucl. Med. 38: 636-643, 1997

Joel Karp

1997

History of the

“Long Scanner” Idea

*W.W. Moses, “2010 – An Instrumentation Odyssey,”

SNM Mid-Winter Meeting, January, 1999.

40 cm Axial FOV

Short Septa

PET Camera in 2010*

Badawi et al, IEEE Trans Nucl

Sci;47:pp.1228–32, 2000

Ramsey Badawi

2000

History of the

“Long Scanner” Idea

D. Crosetto, IEEE Nucl Sci Symp Conf Record

pp. 2415–19, 2003

Dario Crosetto

2003

68 cm Axial FOV – the “BGO cave”

(Hamamatsu SHR-92000)

M. Watanabe, et al., IEEE Trans. Nucl. Sci. NS-

51: pp. 796–800, 2004

History of the

“Long Scanner” Idea

PQ13. Can tumors be detected when they are 2 to 3 orders of magnitude

smaller than those currently detected with in vivo imaging modalities?

NIH R01 CA170874: Enabling technologies for ultra-high sensitivity PET scanners

History of the

“Long Scanner” Idea

History of the

“Long Scanner” Idea

Ramsey

Badawi

Simon

Cherry

Why Hasn’t This

Been Done Before?

• Technology Wasn’t Ready

– Development of LSO (low dead time allows septa-less operation,

necessary for long FOV)

– More stable / reliable detector modules

– Time-of-Flight (more effective sensitivity)

– Bigger disks & FPGAs (able to take data)

– 3-D reconstruction algorithms

– OSEM (reconstruct images in finite time)

– Faster computers / more memory (reconstruct in finite time)

– Scatter correction algorithms

– Point Spread Function correction

•Clinical Applications Weren’t Ready

– Lot’s to be done with oncology

– Applications gradually demanding longer FOV

Industry Advisory Panel:

Chuck Stearns (GE Healthcare)

Michael Casey (Siemens)

Matthias Schmand (Siemens)

Ling Shao (Philips Healthcare)

Medical Advisory Board:

Richard Wahl (Johns Hopkins)

David Mankoff (Univ. of Pennsylvania)

Michael Graham (Univ. of Iowa)

William Jagust (LBNL)

Pat Price (Imperial College)

Senior Advisors:

Thomas Budinger

Michael Phelps

Ramsey Badawi

Simon Cherry

Jinyi Qi

Terry Jones

Julien Bec

Eric Berg

Martin Judenhofer

Emilie Roncali

Jonathan Poon

Xuezhu Zhang

William Moses

Qiyu Peng

Woon-Seng Choong

Joel Karp

Suleman Surti

Srilalan Krishnamoorthy

EXPLORER Team

Design Parameters

Siemens mCT EXPLORER

Axial FOV (cm) 21.8 200

Ring diameter (cm) 84.9 ~80

Scintillator LSO LYSO

Spatial resolution (mm) 4.1 <4

TOF resolution (ps) 530 <400

Integrated CT unit? Yes Yes

DOI Measurement? No Yes No

Sensitivity Improvement

mCT EXPLORER Ratio

Point Source in Air at FOV Center 24.9% 92.9% 3.7

Point Source w/ Attenuation(27 cm dia. x 200 cm long)

1.6% 3.9% 2.4

Whole Body NECR, 10 mCi(27 cm dia. x 200 cm long)

75.7 2,560 33.8

Pediatric NECR, 0.05 mCi(20 cm dia. x 70 cm long)

3.12 48.0 15.5

Brain VOXTISS 8 NECR, 10 mCi6:1 activity

176 597 3.4

Cardiac VOXTISS 8 NECR, 20 mCiall activity in heart

613 1910 3.1

• Non-TOF Values for NECR Given

• Multiply NECR by 1.4 – 2.8 to Obtain NECRTOF

NECR Comparison

Whole Body

(27 cm dia., 200 cm long)

Challenges

• Scale of System

– ~1M scintillator crystals

– 600 kg of scintillator

• Mechanical Issues

– Structural support

– Access for repair

– Thermal management

(especially if SiPMs used)

• Event Rates (10 mCi in FOV)

– 150 million singles/sec

– 50 million coincidences/sec

– 12 GB/sec data rates

– ~10-40 TB storage per day

Gantry Design

• 5 Separate Gantries w/ Interlocking Covers

• Separable (via Rail System) for Servicing

Electronics Architecture

Detector Crate

Detector Crate

Detector Crate

Detector Crate

Detector Crate

Detector Crate

Detector Crate

Detector Crate

Detector Crate

Detector Crate

Detector Crate

Detector Crate

• Singles Events Processed

by Detector Crates

– One crate services long strip

of modules

• Low Data Rates

– Real-time coinc. processing

– Singles searched for pairs in

different detector crates

– Coincident evts written to disk

• High Data Rates

– Offline coinc. processing

– Crate independently writes

singles events to its own disk

• Module Event Rates Same as Conventional PET

• “Standard” Electronics for Each Detector Module

Current Status

• Simulations and prototype detectors,

electronics and reconstruction

methods completed

• Discussions with potential partner

companies almost complete

• Goal is operational scanner

within 2 years

• “Monkey EXPLORER” prototype

fabricated and ready for initial

testing. Prototype is reconfigured

Siemens mCT camera:

– 40 cm diameter (half mCT dia.)

– 44 cm axial (twice mCT axial)

7 mm

6 mm

5 mm

4 mm

3 mm

2 mm

Image reconstruction:- 1 x 1 x 2 mm voxel size, ~390M events- OSEM (10 iterations, 20 subsets) with resolution modelling- Analytical attenuation correction. No other corrections (normalization, scatter, randoms)

Partner Company

Selection

• Detector Module Performance

– Reliability & stability!!!

– TOF resolution

• Engineering Provided

– “Detector Panel” design

– Cooling / thermal management

– Coincidence electronics

• “Completeness” of Software

– Calibration & setup software

– Data correction software

– Reconstruction software

• “Business” Considerations

– Cost & delivery time

– In commercial product roadmap?

Image Better

EXPLORERConventional PET

• > 6-fold improvement

in SNR

– Reconstruct at higher

spatial resolution

– Detect smaller lesions

– Detect low-grade

disease

– Better statistics for

kinetic modeling

Image Better:

Micrometastases

• Clinical Need

– 140,000 new colorectal diagnoses in US / year

– 60% have adjuvant chemotherapy post-surgery

– 40% are unnecessary (no micrometastases)

• Accurately Image Micrometastases (0.2–6 mm)

– Normal FDG injection (10 mCi)

– Image 330 minutes post-injection (3 half lives)

– Because of tumor kinetics, higher tumor contrast

– Improved sensitivity enables high quality imaging

*Price P M, Badawi R D, Cherry S R , Jones T.Journal of Nuclear Medicine 2014;55:696-697

Image Longer

time

EXPLORER

Conventional PET

• Major increase in dynamic range

can image for 5 more half lives

• 11C> 3 hours

• 18F> 16 hours

• 89Zr> 30 days

Image Longer:11C Imaging / Kinetics

b

c

N

O

ON

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HO

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OMe

O

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O

PS O-

N

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ON

O

O

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Me

OH

N

N

N

O

NH2NNa+

Na+

CH3

CH3

CH3

*

*

*

Time (minutes)

0 15 30 45 60 75 90 105

[11C

] L

Y2

18

13

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n (

ng

/mL

)

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Bile duct

Bowel near bile outflow

Bowel

Time (minutes)

0 15 30 45 60 75 90 105

0

100

200

300

400

500Kidney

Ureter

Spleen

Vertebra

Antisense Oligonucleotide 11C-LY2181308 Uptake

Image Faster

EXPLORER

• Total-body PET in

15-30 seconds

– Image in a single

breath hold

– Reduce effects of

respiratory motion

– Total-body kinetic

imaging with high

temporal resolution

10-20 mins

Conventional PET

15-30 secs

Image Faster:

Mind / Body Interaction

Anxiety Disorder

Bipolar Disorder

Insomnia

Post-traumatic Stress Disorder

Borderline Personality Disorder

ADHD

Major Depressive Disorder

Chronic Fatigue Syndrome

Fibromyalgia

Irritable Bowel Syndrome

Alcoholism

Burnout

Image Gently (Low Dose)

EXPLORER

Conventional PET

• 40-fold reduction in dose

– Whole-body PET at

~0.15 mSv

– Annual natural background

is ~2.4 mSv

– Return flight (SFO-LHR) is

~0.11 mSv

– PET can be used with

minimal risk – new

populations

Image Gently (Low Dose):

Maternal / Fetal Interaction

• Clinical Need

– 15M babies born pre-term (<37 weeks) / year

– 1.1M die because of pre-term complications / year

– Many surviving pre-term babies have problems as adults

(disabled, diabetes, hypertension, heart disease, obesity)

• Identify Problems In Utero

– Trace nutrient transport from mother to fetus

(oxygen, glucose, amino acids, fatty acids)

– Image at <0.05 mSv

• One week of natural background radiation in UK

• Flight between London and San Francisco

Image More Often

EXPLORER

Conventional PET

Image More Often:

Precision Medicine

• Clinical Need

– Heterogeneity in cancer

– Individualized treatment

desired

• Multiple PET Imaging

Sessions

– Suggest best therapies

– Follow treatment

– Assess response to therapy

• Add pharmacokinetics?

– Modify treatment according

to response

11C-DACA Whole Body Distribution

11C-DACA Kinetics

Transformative Areas

of Investigation

Detecting occult low density

multi-system disease

– Ultra-staging of micro-metastases

– Plaques in atherosclerosis

– Inflammation

– Infection

Providing total body kinetics

– Drug delivery / extended time courses /

physiologically based pharmaco-kinetic

models

– Translational pipeline for new

radio-labelled imaging biomarkers

– Toxicology

Studying the interactions between

the body’s organs

–Distribution of tissue blood flow

Enabling low radiation dose studies

– Repeat studies & normal subjects

– Young patients

– Maternal-Fetal

Studying interactive regional

pathologies brain: body

– Anxiety / Depression

– Alzheimer’s Disease

– Metabolic syndrome / obesity

Longitudinal studies

– Precision therapy

– Progressive disease (arthritis, diabetes)

Expanding the commercial future

– Higher clinical throughput

– New applications

Comments & Questions?

Overview of Imaging-Current status from medical

perspective

Pat Price

Imperial College London

2nd Divonne Brainstorming meeting on CERN Medical Applications

Current status from medical prospective

Current clinical use• Anatomical-invasive/real time (RT)• Diagnostic• Functional• Ex-vivo

All need • Increased sensitivity/resolution• Increased specificity• Increased biological information

Imaging in Development of surgery

The Magnetic Resonance

Imaging–Linac System

Jan J.W. Lagendijk, et al Seminars in Radiation Oncology, Volume 24, Issue 3, 2014, 207–209

Cryo-electron microscopy

• Cryogenic Transmission Electron microscope for high-resolution single particle analysis

• Cryo-tomography of biological samples

– Detecting occult low density multi-system disease Ultra-staging of micro-metastases Plaques in atherosclerosis Inflammation Infection.

– Providing total body kinetics Drug delivery /extended time courses /physiologically based PK models Translational pipe line for new radio-labelled imaging biomarkers Toxicology.

– Enabling Low radiation dose studies Repeat studies Normal subjects Young patients Maternal-Fetal

– Studying interactive regional pathologies brain: body Anxiety/Depression Alzheimer’s Disease Metabolic syndrome/Obesity.

-- Studying the interactions between the body’s organs– Expanding the commercial future

New applications Higher clinical throughput.

Total body PET Transformative areas of investigative medicine:

– Detecting occult low density multi-system disease Ultra-staging of micro-metastases Plaques in atherosclerosis Inflammation Infection.

– Providing total body kinetics Drug delivery /extended time courses /physiologically based PK models Translational pipe line for new radio-labelled imaging biomarkers Toxicology.

– Enabling Low radiation dose studies Repeat studies Normal subjects Young patients Maternal-Fetal

– Studying interactive regional pathologies brain: body Anxiety/Depression Alzheimer’s Disease Metabolic syndrome/Obesity.

-- Studying the interactions between the body’s organs– Expanding the commercial future

New applications Higher clinical throughput.

Total body PET Transformative areas of investigative medicine:

Detecting Micro-Metastatic Cancer-The Challenge

No Mets ITC1cell-<0.2mm

Micro Mets

0.2-6mm

Subclinical

6-9mm

Clinical

>1cm

PET Ultra-staging PET MRI CT USS

60 min 18FDG

Current cancer imaging with 18FDG

The challenge micro-metastases

Economics of Better Selection for Adjuvant Chemotherapy

• In the USA alone 140,000 patients diagnosed with colorectal cancer per year. 60% late stage receive adjuvant chemotherapy after surgery

• 44% of post surgical patient do not need adjuvant chemotherapy as do not have micrometastases

• Clinical trials of novel adjuvant therapy based on 5 years survival so long and expensive

• Similar challenges in Neoadjuvant therapy

• Similar issues with breast/lung/prostate etc

HypothesisFor ultra-staging in cancer*

The total body Ultra PET scanner will be 40times more sensitive than conventional scannersfor whole body imaging

&

By waiting 3 half lives; 330 minutes postadministration of 18FDG, the enhanced contrastwill make it possible to measure raised levels ofactivity in organs which correspond to thepresence of microscopic cancer

*Price P M, Badawi R D, Cherry S R , Jones T.Journal of Nuclear Medicine 2014;55:696-697

90 mins after injection

– Detecting occult low density multi-system disease Ultra-staging of micro-metastases Plaques in atherosclerosis Inflammation Infection.

– Providing total body kinetics Drug delivery /extended time courses /physiologically based PK models Translational pipe line for new radio-labelled imaging biomarkers Toxicology.

– Enabling Low radiation dose studies Repeat studies Normal subjects Young patients Maternal-Fetal

– Studying interactive regional pathologies brain: body Anxiety/Depression Alzheimer’s Disease Metabolic syndrome/Obesity.

-- Studying the interactions between the body’s organs– Expanding the commercial future

New applications Higher clinical throughput.

Total body PET Transformative areas of investigative medicine:

b

c

N

O

ON

O

O

O

PS

HO

O-

Me

OMe

O

O

O

OMe

O

PS O-

N

O

ON

O

O

O

OMe

Me

OH

N

N

N

O

NH2NNa+

Na+

CH3

CH3

CH3

*

*

*

Time (minutes)

0 15 30 45 60 75 90 105

[11C

] L

Y2

18

13

08

co

nc

en

tra

tio

n (

ng

/mL

)

0

100

200

300

400

500Liver

Bile duct

Bowel near bile outflow

Bowel

Time (minutes)

0 15 30 45 60 75 90 105

0

100

200

300

400

500Kidney

Ureter

Spleen

Vertebra

Antisense Oligonucleotide Carbon-11-LY2181308 Uptake

Perfusion Dependant Drug Delivery Due to Tumour Microscopic

Heterogeneity

Uniform Perfusion Heterogeneous PerfusionNormal Perfusion

Transit of an inert freely diffusible tracer

Diffusion space

(Physiologically

Exchanging Space)

Inadequate Perfusion

Diffusion space

(Physiologically

Exchanging Space)

NecrosisNormal perfusion

Transit of an inert freely diffusible tracer

Measuring Tumour Heterogeneity with High sensitivity PET

– Detecting occult low density multi-system disease Ultra-staging of micro-metastases Plaques in atherosclerosis Inflammation Infection.

– Providing total body kinetics Drug delivery /extended time courses /physiologically based PK models Translational pipe line for new radio-labelled imaging biomarkers Toxicology.

– Enabling Low radiation dose studies Repeat studies Normal subjects Young patients Maternal-Fetal

– Studying interactive regional pathologies brain: body Anxiety/Depression Alzheimer’s Disease Metabolic syndrome/Obesity.

-- Studying the interactions between the body’s organs– Expanding the commercial future

New applications Higher clinical throughput.

Total body PET Transformative areas of investigative medicine:

Maternal-Fetal Health

• 15M babies/year are born pre-term (<37 weeks) “born too soon”

• 1.1M babies die/year because of pre-term complications

• Many surviving pre-term babies are disabled

• 3M still born babies per year

• Intrauterine growth restriction (IUGR) is due to abnormal placenta function

Intrauterine Growth Restrictionis associated with

• Raised neonatal mortality and morbidity

• Diabetes in adulthood

• Hypertension in adulthood

• Ischemic heart disease in adulthood

• Metabolic syndrome (obesity)

The Case for Maternal-Fetal PETTracing nutrient from the mother to the fetus

(Placenta transport e.g. oxygen, glucose, amino acids, fatty acids)

Drugs and toxins distribution between mother to fetus

Metabolic health of the fetus

Inflammation/infection

Schizophrenia

Autism

Cognitive impairment

Maternal cardiovascular physiology

Placenta transporters

Aim:

Enable the collection of biologically

meaningful PET data at a “cost” of < 0.05mSv

One week of natural background radiation in the UK

One way flight between London-San Francisco

Breaking through the radiation absorbed dose barrier

The potential for low dose functional studies in maternal-fetal medicine using combined PET and MRI Terry Jones and Thomas F. Budinger. Journal of Nuclear Medicine 2013, 54: 2017-2018

Cost (radiation dose)

vs

Benefit (immediate & lifetime impact)

Maternal-Fetal PET

Imaging at the beginning of life and not just at the end

– Detecting occult low density multi-system disease Ultra-staging of micro-metastases Plaques in atherosclerosis Inflammation Infection.

– Providing total body kinetics Drug delivery /extended time courses /physiologically based PK models Translational pipe line for new radio-labelled imaging biomarkers Toxicology.

– Enabling Low radiation dose studies Repeat studies Normal subjects Young patients Maternal-Fetal

– Studying interactive regional pathologies brain: body Anxiety/Depression Alzheimer’s Disease Metabolic syndrome/Obesity.

-- Studying the interactions between the body’s organs– Expanding the commercial future

New applications Higher clinical throughput.

Total body PET Transformative areas of investigative medicine:

The Complexity of the City[Economy/Culture]

Financial

Legal

Health Care

Education

The ArtsRetail

Transport

Energy supplyEthnic Groups

Administration

Using Total Body PET to study the Complexity of the Human Body

Complex organs & tissues/Interacting in a complex system e.g.:• Heart-blood circulation• Brain-Body• Hormone & Peptide producing organs

e.g.: Pancreas/Adrenals/Thyroid/Gut/Gonads

• Mother-fetus

To date Imaging has focused on individual organs

Anxiety Disorder

Bipolar Disorder

Insomnia

Posttraumatic Stress Disorder,

Borderline Personality Disorder,

ADHD

Major Depressive Disorder,

Burnout, Chronic Fatigue Syndrome

Fibromyalgia

Irritable Bowel Syndrome,

Alcoholism

Stress and disease

Brain-Body Positron Emission Tomography

Depression & Anxiety

Psychosis

Projected Applications

of

Total Body PET

Psychiatry

Inflammation

Hypothalamic-Pituitary-Adrenal (HPA) Axis

Gut-Brain Axis

Irritable Bowel Syndrome

Pre-Partum

Post-Partum

Puberty

Hormonal Dependant

1

2

:

Psychiatry

The 10 Year Vision

Using Total Body PET:Molecular/Functional Imaging of the

total body with high sensitivity“Systems Biology”

Clinical Research

Health Care

in

Risks:Foetal Radiation Absorbed - Dose Estimates

0.1mSv/18.5 MBq of 11C administered

Tom Budinger

0.1mSv

Return Flight London-San Francisco: 0.11 mSv