The next era of renal radionuclide imaging: novel PET radiotracers

Werner, Rudolf A.; Chen, Xinyu; Lapa, Constantin; Koshino, Kazuhiro; Rowe, Steven P.; Pomper, Martin G.; Javadi, Mehrbod S.; Higuchi, Takahiro

doi:10.1007/s00259-019-04359-8

Cited by 32 publications

(31 citation statements)

References 54 publications

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“…Volumes of interest derived by PET studies that cover "areas at risk" in the renal cortex or medulla may allow monitoring of renal injury after radiation or may even have predictive potential prior to therapy. Given these benefits, several PET radiotracers have been evaluated for renal imaging with promising results (2,7). With the benefits of a longer radiological half-life, 18 F-FDS has also been recently evaluated as a potential renal imaging agent (as a replacement for 99m Tc-DTPA) in healthy and diseased rats as well as healthy human subjects (24)(25)(26).…”

Section: Spatiotemporal Resolution and Renal Kinetics Of 11 C-paba Inmentioning

confidence: 99%

“…While these techniques are still widely used in clinical practice, they have some major limitations including two-dimensional information with a concomitant lack of accurate anatomic correlation, low spatial resolution, and low signal/background ratios. The soft-tissue attenuation may also reduce diagnostic accuracy and limit reliable quantification (2). Implementation of single-photon emission computed tomography (SPECT) for renal imaging led to improvements in image contrast and spatial resolution.…”

Section: Introductionmentioning

confidence: 99%

“…Consequently, PET requires administration of much lower doses of radioactivity and provides higher accuracy measurements of regional radiopharmaceutical tissue concentrations (2)(3)(4).…”

Section: Introductionmentioning

confidence: 99%

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¹¹C-PABA as a PET Radiotracer for Functional Renal Imaging: Preclinical and First-in-Human Study

et al. 2020

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para-Aminobenzoic acid (PABA) has been previously used as an exogenous marker to verify completion of 24-hour urine sampling. Therefore, we hypothesized that radiolabeled PABA with 11 C could allow high-quality dynamic PET of the kidneys while reducing the radiation exposure due to its short biological and physical half-lives. We evaluated if 11 C-PABA could visualize renal anatomy and quantify function in healthy rats, rabbits, and first-inhuman studies in healthy volunteers. Methods: Healthy rats and rabbits were injected with 11 C-PABA intravenously. Subsequently, a dynamic PET was performed followed by post-mortem tissue biodistribution studies. 11 C-PABA PET was directly compared with the current standard, 99m Tc-MAG3 in rats. Three healthy human subjects also underwent dynamic PET after intravenous injection of 11 C-PABA. Results: In healthy rats and rabbits, dynamic PET demonstrated a rapid accumulation of 11 C-PABA in the renal cortex, followed by rapid excretion through the pelvicalyceal system. In humans, 11 C-PABA PET was safe and well tolerated. There were no adverse or clinically detectable pharmacologic effects in any subject. The cortex was delineated on PET, and the activity gradually transited to the medulla and then renal pelvis with high spatiotemporal resolution. Conclusion: 11 C-PABA demonstrated fast renal excretion with very low background signal in animals and humans. These results suggest that 11 C-PABA could be used as a novel radiotracer for functional renal imaging, providing high-quality spatiotemporal images with low radiation exposure.

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Section: Spatiotemporal Resolution and Renal Kinetics Of 11 C-paba Inmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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¹¹C-PABA as a PET Radiotracer for Functional Renal Imaging: Preclinical and First-in-Human Study

et al. 2020

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“…Most recently, 99m Tc-MAG3 SPECT was used to assess dynamic renal changes from 177 Lu-DOTA-TATE therapy in mice [38]. Recent years have also seen the development of new renal PET tracers, such as [ 68 Ga]Ga-EDTA and [ 18 F]fluorosorbitol (FDS), which allow for imaging with better resolution and quantification [63]. Assessment aside, strategies to reduce kidney toxicity in PSMA therapy have also been developed and tested.…”

Section: Kidneysmentioning

confidence: 99%

The increasing potential of nuclear medicine imaging for the evaluation and reduction of normal tissue toxicity from radiation treatments

Mohan

Bruin

Kamer

et al. 2021

Eur J Nucl Med Mol Imaging

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Radiation therapy is an effective treatment modality for a variety of cancers. Despite several advances in delivery techniques, its main drawback remains the deposition of dose in normal tissues which can result in toxicity. Common practices of evaluating toxicity, using questionnaires and grading systems, provide little underlying information beyond subjective scores, and this can limit further optimization of treatment strategies. Nuclear medicine imaging techniques can be utilised to directly measure regional baseline function and function loss from internal/external radiation therapy within normal tissues in an in vivo setting with high spatial resolution. This can be correlated with dose delivered by radiotherapy techniques to establish objective dose-effect relationships, and can also be used in the treatment planning step to spare normal tissues more efficiently. Toxicity in radionuclide therapy typically occurs due to undesired off-target uptake in normal tissues. Molecular imaging using diagnostic analogues of therapeutic radionuclides can be used to test various interventional protective strategies that can potentially reduce this normal tissue uptake without compromising tumour uptake. We provide an overview of the existing literature on these applications of nuclear medicine imaging in diverse normal tissue types utilising various tracers, and discuss its future potential.

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“…PET imaging has attracted growing interest for accurate diagnosis, prognosis evaluation, and therapy monitoring due to its excellent sensitivity and quantitative measurement property. A great variety of positron‐emitting isotopes that can be classified into radiometals (e.g., 64 Cu, 68 Ga, and 89 Zr) and non‐metals (e.g., 11 C, 13 N, 15 O, and 18 F) become available for PET imaging . These isotopes show distinct decay time ranging from a few minutes to hundreds of days depending on their intrinsic physicochemical properties.…”

Section: Radiolabeled Dendrimer‐based Nanodevices For Targeted Nucleamentioning

confidence: 99%

PAMAM Dendrimer‐Based Nanodevices for Nuclear Medicine Applications

Xiao

Shi

et al. 2019

Macromolecular Bioscience

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Nuclear medicine, involving nuclear medicine imaging and radiotherapy (RT), has become a mainstay of theranostics in the field of nanomedicine and several examples have been successfully translated into clinical practice. The combination of radionuclides with dendrimers has long been investigated in nuclear imaging, such as positron emission tomography (PET) and single‐photon emission computed tomography (SPECT), providing functional information for whole body quantitative analysis with high sensitivity due to the unique structural advantages of the dendrimer platform. Besides, radioisotopes with both therapeutic and imaging functionalities can also be combined with dendrimer platforms for theranostic applications. In this review, the recent advances in the development of radionuclide‐labeled poly(amidoamine) dendrimer‐based nanodevices for targeted PET, SPECT, SPECT/computed tomography, SPECT/magnetic resonance imaging of tumors, RT, as well as for SPECT‐imaging‐guided RT of cancer are summarized. Current restrictions hindering the clinical translation of dendrimer‐based nuclear nanodevices and future prospects are also discussed.

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The next era of renal radionuclide imaging: novel PET radiotracers

Cited by 32 publications

References 54 publications

¹¹C-PABA as a PET Radiotracer for Functional Renal Imaging: Preclinical and First-in-Human Study

¹¹C-PABA as a PET Radiotracer for Functional Renal Imaging: Preclinical and First-in-Human Study

The increasing potential of nuclear medicine imaging for the evaluation and reduction of normal tissue toxicity from radiation treatments

PAMAM Dendrimer‐Based Nanodevices for Nuclear Medicine Applications

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The next era of renal radionuclide imaging: novel PET radiotracers

Cited by 32 publications

References 54 publications

11C-PABA as a PET Radiotracer for Functional Renal Imaging: Preclinical and First-in-Human Study

11C-PABA as a PET Radiotracer for Functional Renal Imaging: Preclinical and First-in-Human Study

The increasing potential of nuclear medicine imaging for the evaluation and reduction of normal tissue toxicity from radiation treatments

PAMAM Dendrimer‐Based Nanodevices for Nuclear Medicine Applications

Contact Info

Product

Resources

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¹¹C-PABA as a PET Radiotracer for Functional Renal Imaging: Preclinical and First-in-Human Study

¹¹C-PABA as a PET Radiotracer for Functional Renal Imaging: Preclinical and First-in-Human Study