The Molecular Imaging Branch (MIB) aims to exploit positron emission tomography (PET) as a radiotracer imaging technique for investigating neuropsychiatric disorders, such as depression, addiction, schizophrenia and Alzheimer's disease. Fundamental to the mission of the MIB is the development of novel radioactive probes (radiotracers) that can be used with PET to deliver new and specific information on molecular entities and processes in living animal or human brain (e.g., regional neuroreceptor densities, neurotransmitter synthesis, enzyme concentrations, regional metabolism, amyloid deposition, drug efflux from brain). PET is a uniquely powerful and sensitive imaging modality for such purposes when successfully coupled to appropriate PET radiotracers. The chemical development of new radiotracer types is the key to exploiting the full potential of PET in neuropsychiatric research. Such radiotracer development is widely recognized as being a highly challenging and demanding scientific task. In fact, potential interesting imaging targets far exceed the range of available and useful radiotracers. Within MIB, our laboratory, the PET Radiopharmaceutical Sciences Section, places a concerted effort on all medicinal chemistry and radiochemical aspects of PET radiotracer discovery. This research activity has some parallels with drug discovery in terms of required effort and risk, because successful PET probes must fulfill a difficult-to-satisfy range of chemical, pharmacological and biological criteria. In support of our mission,our laboratories are equipped with facilities for performing medicinal chemistry and automated radiochemistry with positron-emitting carbon-11 (t1/2 = 20 min) and fluorine-18 (t1/2 = 110 min). These two short-lived radioisotopes are available to us daily from the adjacent cyclotrons of the NIH Clinical Center (Chief Dr. P. Herscovitch). Our program currently focuses on developing novel probes for studying many different brain receptors or proteins that are implicated in neuropsychiatric disorders. Examples are cannabinoid (CB-1, CB-2), serotonin (5-HT1A, 5-HT4), TSPO (formerly known as PBR), nociceptin (NOP), histamine-H3, oxytocin and glutamate (mGlu1, mGlu5)receptors, efflux transporters (P-gp) and protein deposits such as beta-amyloid. Our Section interacts seamlessly with the Imaging Section of our Branch (Chief: Dr. R.B. Innis) for early evaluation of potential radiotracers in animals. Subsequent PET research in human subjects is also performed in collaboration with the Imaging Section under Food and Drug Administration (FDA) oversight through 'exploratory'or full investigational new drug applications (expINDs or INDs). Our research has been successful in providing a stream of new radiotracers for CB-1, TSPO, mGluR5, NOP and P-gp for brain imaging in human subjects in support of clinical research and drug development. Two radiotracers (C-11PBR28 and F-18FBR), developed successfully for TSPO imaging, are starting to have application for the investigation of brain inflammatory conditions in response to neurological insults e.g., traumatic brain injury, stroke, epilepsy and neurodegeneration (Alzheimer's disease). Other institutions (e.g., Pitsburgh University) are also begining to use these radiotracers to perform clinical studies. An interesting and unexpected finding is that healthy human subjects can have one or both of two different forms of TSPO that interact differently with C-11PBR28. New less discriminatory TSPO radioligands would therefore be useful and are under development. CB-1 receptors are the protein sites in brain that are acted upon by cannabis. Our new CB-1 radiotracers (C-11MePPEP, F-18FMPEP) have potential for the study of drug addiction, including alcoholism and cocaine addiction, and other disorders, such as obesity. Indeed, a recent study from our Branch with 11CMePPEP reveals definite changes in brain CB1 receptors in response to cannabis use. The use of C-11MEPPEP is also being taken uup elsewhere. Our mGluR radiotracers (F-18SP203, C-11SP203) are expected to have value for the study of Fragile X syndrome, addiction, autism and schizophrenia. Such PET radiotracers can have additional value in expediting drug discovery, since potentially they may be used in drug-receptor occupancy (RO)studies to determine dosing regimes to be used in clincial trials. The imaging of drug efflux pump (e.g., P-gp) function at the blood-brain barrier is an area of interest in our laboratory with relevance to drug development for neuropsychiatric disorders. We have developed a much improved radiotracer, named C-11dLop, for this purpose. C-11dLop may have value for assessing the role of efflux pumps in Alzheimer's disease and other neurodegenerative disorders (e.g., Parkinson's disease). A radiotracer for imaging P-gp density is sought in addition to our radiotracer of function. Radiotracers capable of measuring increased efflux transporter action are also being developed. Some of the radiotracers that we have developed are likely to have value for diseases that present outside the brain. Thus, the TSPO radiotracers may be generic for the study of inflammation in the periphery (e.g., as occurs in atherosclerosis), and the P-gp radiotracer for the study of cancer (especially multi-drug resistance). Methodology underpinning our radiotracer development was also advanced in areas such as the development of new synthetic methods, new radiolabeling procedures, and the application of micro-reactors to the miniaturization of radiochemistry. We have combined the use of microfluidics with a new F-18 labeling strategy to great effect, thereby expanding the number and type of candidate F-18 labeled radiotracers that may be produced. Such advances are seen as being vital for facilitating radiotracer applications. New analytical methods, based on for example liquid chromatography coupled to mass spectrometry (LC-MS), have also been developed and exploited to understand the biochemical fate of radiotracers in living systems. This information is needed to fully understand the results from PET experiments and to derive meaningful output measures, such as brain receptor concentrations. Sensitive LC-MS/MS has been introduced for the measurement of radiotracer half-life and specific radioactivity, and is also being investigated for the measurement of radiotracer concentration in blood following intravenous administration. The use of LC-MS/MS avoids the need to measure fast-decaying radioactivity. Productive collaborations have been established with external academic chemistry and medicinal chemistry laboratories, nationally and internationally, and also with pharmaceutical companies through CRADAs (Cooperative Research and Development Agreements) and the Biomarker Consortium of the Foundation for NIH. Productive collaborations also exist with other centers working with PET and its associated radiochemistry and radiotracer development. The laboratory is active in training new scientists for this field at all levels. In addition, we produce some useful radiotracers that have been devloped elsewhere for PET investigations in animal or human subjects e.g.,C-11CUMI (5-HT1A receptor imaging), C-11rolipram (PDE4 enzyme imaging). The production of such radiotacers for use in human subjects also complies with (Food and Drug Administration) FDA requirements under exploratory or full Investigational New Drug applications (INDs). Each PET experiment with any radiotracer requires a radiosynthesis of the radiotracer on the same day, and hence radiotracer production is a regular activity. Approximately 400 productions are performed per annum.

Project Start
Project End
Budget Start
Budget End
Support Year
10
Fiscal Year
2011
Total Cost
$3,330,051
Indirect Cost
Name
U.S. National Institute of Mental Health
Department
Type
DUNS #
City
State
Country
Zip Code
Paul, Soumen; Gallagher, Evan; Liow, Jeih-San et al. (2018) Building a database for brain 18 kDa translocator protein imaged using [11C]PBR28 in healthy subjects. J Cereb Blood Flow Metab :271678X18771250
Kim, Min-Jeong; Shrestha, Stal S; Cortes, Michelle et al. (2018) Evaluation of Two Potent and Selective PET Radioligands to Image COX-1 and COX-2 in Rhesus Monkeys. J Nucl Med :
Ooms, Maarten; Tsujikawa, Tetsuya; Lohith, Talakad G et al. (2018) [11C]( R)-Rolipram positron emission tomography detects DISC1 inhibition of phosphodiesterase type 4 in live Disc1 locus-impaired mice. J Cereb Blood Flow Metab :271678X18758997
Singh, Prachi; Shrestha, Stal; Cortes-Salva, Michelle Y et al. (2018) 3-Substituted 1,5-Diaryl-1 H-1,2,4-triazoles as Prospective PET Radioligands for Imaging Brain COX-1 in Monkey. Part 1: Synthesis and Pharmacology. ACS Chem Neurosci :
Kim, Sung Won; Wiers, Corinde E; Tyler, Ryan et al. (2018) Influence of alcoholism and cholesterol on TSPO binding in brain: PET [11C]PBR28 studies in humans and rodents. Neuropsychopharmacology 43:1832-1839
Shrestha, Stal; Singh, Prachi; Cortes-Salva, Michelle Y et al. (2018) 3-Substituted 1,5-Diaryl-1 H-1,2,4-triazoles as Prospective PET Radioligands for Imaging Brain COX-1 in Monkey. Part 2: Selection and Evaluation of [11C]PS13 for Quantitative Imaging. ACS Chem Neurosci :
Fisher, Martin J; McMurray, Lindsay; Lu, Shuiyu et al. (2018) [Carboxyl-11 C]Labelling of Four High-Affinity cPLA2? Inhibitors and Their Evaluation as Radioligands in Mice by Positron Emission Tomography. ChemMedChem 13:138-146
Naumiec, Gregory R; Cai, Lisheng; Lu, Shuiyu et al. (2017) Quinuclidine and DABCO Enhance the Radiofluorinations of 5-Substituted 2-Halopyridines. European J Org Chem 2017:6593-6603
Kobayashi, Masato; Jiang, Teresa; Telu, Sanjay et al. (2017) (11)C-DPA-713 has much greater specific binding to translocator protein 18?kDa (TSPO) in human brain than (11)C-( R)-PK11195. J Cereb Blood Flow Metab :271678X17699223
Lee, Yong-Sok; Chun, Joong-Hyun; Hodoš?ek, Milan et al. (2017) Crystal Structures of Diaryliodonium Fluorides and Their Implications for Fluorination Mechanisms. Chemistry 23:4353-4363

Showing the most recent 10 out of 151 publications