Use of PET Imaging to Evaluate Transporter‐Mediated Drug‐Drug Interactions

Langer, Oliver

doi:10.1002/jcph.722

Cited by 52 publications

(62 citation statements)

References 103 publications

(232 reference statements)

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“…In parallel to the acceptance of transporters as the key protein systems allowing the crossing of solutes over biological membranes (Giacomini et al, 2010;Hillgren et al, 2013;Suzuki & Sugiyama, 2000; van Montfoort et al, 2003), the role of drug transporters in imaging is increasingly being appreciated (Kannan et al, 2009;Kilbourn, 2017;Kusuhara, 2013;Langer, 2016;Mann et al, 2016;Marie et al, 2017;Stieger et al, 2012;Testa et al, 2015;Van Beers et al, 2012). Noninvasive imaging methods have therefore been developed to reveal and quantify drug transporter function in clearance and non-clearance organs, as a prerequisite to the local pharmacologic/toxicological effect, metabolism and elimination.…”

Section: Introductionmentioning

confidence: 99%

Imaging techniques to study drug transporter function in vivo

Tournier

Stieger

Langer

2018

Pharmacology & Therapeutics

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Transporter systems involved in the permeation of drugs and solutes across biological membranes are recognized as key determinants of pharmacokinetics. Typically, the action of membrane transporters on drug exposure to tissues in living organisms is inferred from invasive procedures, which cannot be applied in humans. In recent years, imaging methods have greatly progressed in terms of instruments, synthesis of novel imaging probes as well as tools for data analysis. Imaging allows pharmacokinetic parameters in different tissues and organs to be obtained in a non-invasive or minimally invasive way. The aim of this overview is to summarize the current status in the field of molecular imaging of drug transporters. The overview is focused on human studies, both for the characterization of transport systems for imaging agents as well as for the determination of drug pharmacokinetics, and makes reference to animal studies where necessary. We conclude that despite certain methodological limitations, imaging has a great potential to study transporters at work in humans and that imaging will become an important tool, not only in drug development but also in medicine. Imaging allows the mechanistic aspects of transport proteins to be studied, as well as elucidating the influence of genetic background, pathophysiological states and drug-drug interactions on the function of transporters involved in the disposition of drugs.

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Section: Introductionmentioning

confidence: 99%

Imaging techniques to study drug transporter function in vivo

Tournier

Stieger

Langer

2018

Pharmacology & Therapeutics

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“…[38][39][40] In this supplement, Langer provides an overview of the use of PET imaging to assess the effect of transportermediated DDIs on drug disposition in various organs such as brain, liver, and kidneys. 41 Further, the author postulates that given the growing importance of membrane transporters with respect to drug safety and efficacy, use of PET in assessment of transportermediated DDIs is expected to play an increasingly important role.…”

Section: Role Of Transporters In Drug Developmentmentioning

confidence: 99%

“…In addition to the use of PBPK modeling to predict tissue concentrations, the role of noninvasive imaging methods such as positron emission tomography (PET) in assessing tissue uptake and interplay between various transporters has been reported in the literature . In this supplement, Langer provides an overview of the use of PET imaging to assess the effect of transporter‐mediated DDIs on drug disposition in various organs such as brain, liver, and kidneys . Further, the author postulates that given the growing importance of membrane transporters with respect to drug safety and efficacy, use of PET in assessment of transporter‐mediated DDIs is expected to play an increasingly important role.…”

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confidence: 99%

Role of Transporters in Drug Development

Arya

Kiser

2016

The Journal of Clinical Pharma

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“…PET is a non‐invasive imaging modality in which physiological and biochemical processes can be studied in vivo following the intravenous administration of a radiolabeled bioactive compound called radiotracer . PET is frequently being used in cardiology, neurology, as well as oncology, and more recently has proven to be a valuable technique in drug discovery …”

Section: Introductionmentioning

confidence: 99%

“…1,2 PET is frequently being used in cardiology, 3 neurology, 4 as well as oncology, 5 and more recently has proven to be a valuable technique in drug discovery. 6,7 The abundance of carbon in organic molecules makes carbon-11 (t 1/2 = 20.4 minutes) an appealing isotope for PET radiotracer development. Carbon-11 is obtained as either [ 11 C]carbon dioxide ([ 11 C]CO 2 ) or [ 11 C]methane from the cyclotron, from which a number of secondary precursors can be obtained by well-established on-line procedures.…”

Section: Introductionmentioning

confidence: 99%

Reaction of ¹¹C‐benzoyl chlorides with metalloid reagents: ¹¹C‐labeling of benzyl alcohols, benzaldehydes, and phenyl ketones from [¹¹C]CO

Roslin

Dahl

Nordeman

2018

Labelled Comp Radiopharmac

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In this article, we describe the carbon-11 ( C, t = 20.4 minutes) labeling of benzyl alcohols, benzaldehydes, and ketones using an efficient 2-step synthesis in which C-carbon monoxide is used in an initial palladium-mediated reaction to produce C-benzoyl chloride as a key intermediate. In the second step, the obtained C-benzoyl chloride is further treated with a metalloid reagent to furnish the final C-labeled product. Benzyl alcohols were obtained in moderated to high non-isolated radiochemical yields (RCY, 35%-90%) with lithium aluminum hydride or lithium aluminum deuteride as metalloid reagent. Changing the metalloid reagent to either tributyltin hydride or sodium borohydride, allowed for the reliable syntheses of C-benzaldehydes in RCYs ranging from 58% to 95%. Finally, sodium tetraphenylborate were utilized to obtain C-phenyl ketones in high RCYs (77%-95%). The developed method provides a new and efficient route to 3 different classes of compounds starting from aryl iodides or aryl bromides.

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Use of PET Imaging to Evaluate Transporter‐Mediated Drug‐Drug Interactions

Cited by 52 publications

References 103 publications

Imaging techniques to study drug transporter function in vivo

Imaging techniques to study drug transporter function in vivo

Role of Transporters in Drug Development

Reaction of ¹¹C‐benzoyl chlorides with metalloid reagents: ¹¹C‐labeling of benzyl alcohols, benzaldehydes, and phenyl ketones from [¹¹C]CO

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Use of PET Imaging to Evaluate Transporter‐Mediated Drug‐Drug Interactions

Cited by 52 publications

References 103 publications

Imaging techniques to study drug transporter function in vivo

Imaging techniques to study drug transporter function in vivo

Role of Transporters in Drug Development

Reaction of 11C‐benzoyl chlorides with metalloid reagents: 11C‐labeling of benzyl alcohols, benzaldehydes, and phenyl ketones from [11C]CO

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Product

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Reaction of ¹¹C‐benzoyl chlorides with metalloid reagents: ¹¹C‐labeling of benzyl alcohols, benzaldehydes, and phenyl ketones from [¹¹C]CO