Assessing the feasibility of intranasal radiotracer administration for in brain PET imaging

Nisha Singh,Mattia Veronese,Jim O'Doherty,Teresa Sementa,Salvatore Bongarzone,Diana Cash,Camilla Simmons,Marco Arcolin,Paul K Marsden,Antony Gee,Federico E Turkheimer

doi:10.1016/j.nucmedbio.2018.08.005

Nisha Singh, Mattia Veronese + Show 9 more

Open Access

https://doi.org/10.1016/j.nucmedbio.2018.08.005

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Abstract

IntroductionThe development of clinically useful tracers for PET imaging is enormously challenging and expensive. The intranasal (IN) route of administration is purported to be a viable route for delivering drugs to the brain but has, as yet, not been investigated for the delivery of PET tracers. If the intranasal (IN) pathway presents a viable option, it extends the PET imaging field by increasing the number of tracers available for human use.Here we report the results of a rodent study testing the feasibility of the IN route to administer radiotracers for brain PET imaging. MethodsWe used two different, well characterised, brain penetrant radiotracers, [18F]fluorodeoxyglucose ([18F]FDG) and [18F]fallypride, and aimed to evaluate the pharmacokinetics after administration of the tracers via the intranasal route, and contrast this to intravenous administration. Image acquisition was carried out after tracer administration and arterial blood samples were collected at different time intervals, centrifuged to extract plasma and gamma counted. We hypothesised that [brain region]:[plasma] ratios would be higher via the intranasal route as there are two inputs, one directly from the nose to the brain, and another from the peripheral circulation. To assess the feasibility of using this approach clinically, we used these data to estimate radiation dosimetry in humans. ResultsContrary to our hypothesis, in case of both radiotracers, we did not see a higher ratio in the expected brain regions, except in the olfactory bulb, that is closest to the nose. It appears that the radiotracers move into the olfactory bulb region, but then do not progress further into other brain regions. Moreover, as the nasal cavity has a small surface area, the extrapolated dosimetry estimations for intranasal human imaging showed an unacceptably high level (15 mSv/MBq) of cumulative skin radiation exposure. ConclusionsTherefore, although an attractive route for brain permeation, we conclude that the intranasal route would present difficulties due to non-specific signal and radiation dosimetry considerations for brain PET imaging.

Highlights

The development of clinically useful tracers for positron emission tomography (PET) imaging is enormously challenging and expensive
Conclusions: an attractive route for brain permeation, we conclude that the intranasal route would present difficulties due to non-specific signal and radiation dosimetry considerations for brain PET imaging
Since the 1990’s there have been several studies assessing the validity of delivering drugs to the brain via the IN route, by-passing the blood brain barrier (BBB) with varying results [2,3,4,5,6]

Summary

Introduction

The development of clinically useful tracers for PET imaging is enormously challenging and expensive. Some examples are peptides like insulin, for the treatment of Alzheimer’s disease [3], and oxytocin, for various neurodevelopmental disorders [11,12] and schizophrenia [13,14]. Another example, esketamine, an IN preparation of S-ketamine for the treatment of unipolar treatment resistant depression [15] that is currently undergoing clinical trials as a viable alternative to intravenous (IV) administration. Ketamine does cross the blood brain barrier when given IV, this is not a practical route for conditions that require prolonged treatment

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