Pharmacokinetics Clinical Trial
Official title:
Assessment of [11C]ER-176 to Image Translocator Protein in Brain and Whole-Body of Healthy Subjects
Background:
- A protein called translocator protein may play a role in brain inflammation. Sometimes it
is present at higher levels in the lungs than in the brain. Researchers want to see if a drug
called [11C]ER176 can provide an image of this protein in the brain.
Objective:
- To test the ability of a drug to image a protein, and test how it is distributed in the
body.
Eligibility:
- Healthy adults over age 18.
Design:
- Participants will be screened with medical history, physical exam, and blood and urine
tests.
- Participants will have a PET scan of the brain using [11C]ER176. It will be injected
through an intravenous tube into 1-2 arm veins. A tube may also be put into an artery at
the wrist or elbow. Some participants will also have a lung scan.
- For the PET, participants will lie on a bed that slides in and out of a doughnut-shaped
scanner. A plastic mask will be molded to their face and head. They may be wrapped with
restraining sheets. The scan will last about 120 minutes. Blood may be taken during the
scan.
- Blood and urine will be taken before and after the scan.
- During another visit, participants will have an MRI scan of the brain. Participants will
lie on a table that slides in and out of a metal cylinder. A strong magnetic field and
radio waves will take pictures of the brain. The scanner makes loud knocking noises.
Participants will be given earplugs.
- Some participants will have only a whole-body PET scan using [11C]ER176.
Objective
Translocator protein 18 kDa (TSPO) is highly expressed in activated microglia and reactive
astrocytes in brain, and it may, thereby, be a useful biomarker of neuroinflammation. We
developed [(11)C]PBR28 as a positron emission tomographic (PET) radioligand to bind to TSPO
and measure its density. Although [(11)C]PBR28 has high in vivo specific signal, it is very
sensitive to the high and low affinity states of TSPO, which are caused by the rs6971 single
nucleotide polymorphism (SNP) in the fourth exon of the TSPO gene resulting in a
nonconservative alanine-to-threonine substitution in position 147 of the encoded TSPO
protein. This co-dominant mutation yields three genetic groups: HH, HL, and LL, where H is
the high-affinity form and L is the low affinity form. The frequency of the L allele is
approximately 30%; thus, the frequency of the LL homozygote is approximately 9%. The affinity
of PBR28 to H and L forms differs about 50 fold; thus, LL carriers provide no measureable
signal in brain from [(11)C]PBR28. We recently developed a new TSPO ligand ER176, the
affinity of which differs by only 1.2 fold and therefore LL carriers should provide
measureable brain uptake. The purpose of this study is to assess the potential of
[(11)C]ER176 to image TSPO in brain, characterize its binding sensitivity in lung of healthy
subjects from all three genetic groups, and to do whole-body imaging for biodistribution and
estimation of radiation dosimetry in humans.
The present protocol will use a new PET ligand [(11)C]ER176 to 1) perform an initial
whole-body scan after [(11)C]ER176 injection in a single healthy volunteer to confirm
wide-spread distribution of radioactivity to different body organs (Phase 0); 2) perform
kinetic brain scans in healthy volunteers of 3 different genotypes, with about half of these
volunteers undergoing lung scans in the same session (Phase 1), and; 3) perform whole-body
imaging in healthy volunteers (Phase 2).
This study will assess the relative robustness of absolute quantitation of TSPO in the brain
of healthy subjects, using an arterial input function and pharmacokinetic modeling. In
addition, lung imaging will provide in vivo binding sensitivity of [(11)C]ER176 to TSPO
genotype. Furthermore, the whole-body imaging would estimate the radiation-absorbed doses for
future use of [(11)C]ER176 in clinical studies.
Study Population
We will select up to 36 healthy adult female and male volunteers (age 18 and older) of 3
different TSPO genotypes for brain imaging, and up to 11 additional healthy volunteers for
whole body dosimetry analysis.
Design
For absolute quantification of TSPO, up to 36 healthy controls (up to 12 each of three TSPO
genotypes) will have brain PET imaging using [(11)C]ER176 and these subjects will have the
arterial line and a brain MRI scan. In about half of those subjects from each genotype group,
lungs will be scanned in the same session. For radiation dosimetry of [(11)C]ER176, up to 11
subjects will have whole-body PET imaging. These subjects will not have arterial line and MRI
scans.
Outcome Measures
The primary outcome measures are: (a) To assess absolute quantitation of TSPO with
[(11)C]ER176, we will determine the identifiability and time stability of distribution volume
in the brain calculated with compartmental modeling. The difference in mean distribution
volumes among subjects with different genotypes would be used to evaluate the genotype
sensitivity of [(11)C]ER176. (b) To assess whole-body biodistribution and dosimetry of
[(11)C]ER176 we will use the organ time-activity curves.
As secondary outcome measure, we will examine the effect of polymorphism on [(11)C]ER176
binding in lungs because lungs have much higher density of TSPO and may be more effective to
show whether ER176 is sensitive to the SNP.
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