Quantitative Whole-body Autoradiography Research Articles

8041 Eneboparatide, A Potent Stimulator Of Urinary Calcium Reabsorption, Induces Prolonged Renal Cortex Retention And PTH1 Receptor Signaling

Abstract Disclosure: G. Ravel: Employee; Self; Amolyt Pharma. R. Datta: Consulting Fee; Self; Amolyt Pharma. S. Milano: Employee; Self; Amolyt Pharma. M. Ovize: Employee; Self; Amolyt Pharma. S. Allas: Employee; Self; Amolyt Pharma. M. Aouadi: None. M.D. Culler: Employee; Self; Amolyt Pharma. Natural parathyroid hormone (PTH) replacement therapy for chronic hypoparathyroidism (cHP) is not ideal due to both short circulating half-life and brief receptor signaling, making the effect too transient. Following agonist binding to the PTH 1 receptor (PTH1R), the magnitude and duration of the receptor signal, and consequently the biological response, appears to depend on the affinity of the ligand for a specific receptor conformation termed R0, which determines the duration of ligand binding. Eneboparatide (Enebo) is a hybrid analog of PTH and PTH-related peptide designed to strongly bind to the R0 conformation while having a short circulating half-life similar to that of PTH. When tested in cHP patients, Enebo eliminated the need for calcium (Ca) (88% patients) and Vitamin D (92% patients) supplementation, while maintaining serum Ca levels over a full 24 hours. Urinary calcium (uCa) was rapidly decreased and was normalized in 92% of patients who were hypercalciuric prior to treatment. To explore the mechanism of the potent effect of Enebo on uCa, a binding assay specific for the R0 conformation of the PTH1R confirmed the high affinity of Enebo versus natural PTH1-34, with IC50 = 1.5nM and 30.9nM, respectively. Postulating that the high-affinity binding of Enebo to R0 should result in longer tissue retention in vivo, we examined the tissue levels of PTH1-34 and Enebo in male, 200-300g rats using quantitative whole-body autoradiography (QWBA) following subcutaneous injection of 3H-labeled Enebo and PTH1-34. Tissue levels of the compounds were normalized based on the concentrations observed in cardiac blood. The highest level observed for both compounds was in the renal cortex, the major site of active PTH-induced Ca reabsorption, with peak concentrations observed 30 minutes post-injection. Six hours after injection, 96.3% of PTH1-34 had disappeared from the renal cortex, as compared with only 61.4% of Enebo, despite both compounds having similar circulating half-lives. With respect to activating the PTH1R, both compounds showed a similar increase in cAMP in human embryonic kidney (HEK293) cells transfected with the PTH1R and the Green Downward cADDis cAMP biosensor, with EC50 of 0.32 and 0.48nM for Enebo and PTH1-34, respectively. To mimic the effect of rapid elimination in vivo, the ligands were added to the cells, washed-off after 15 minutes, and cAMP production followed over the next 16 hours. After washout, the cAMP signal induced by PTH1-34 rapidly returned to baseline in less than 60 minutes, whereas the cAMP signal induced by Enebo gradually decreased and was still evident after 16 hours. Collectively, these data confirm high affinity of Enebo for the R0 conformation of the PTH1R, as well as prolonged receptor signaling and retention by the renal cortex, clearly differentiating Enebo from PTH1-34 and providing strong rationale for the efficacy of Enebo in reducing uCa in cHP patients. Presentation: 6/3/2024

Pharmacokinetics, mass balance, tissue distribution, metabolism, and excretion of [14C]aficamten following single oral dose administration to rats

The pharmacokinetics, metabolism, excretion, mass balance, and tissue distribution of [14C]aficamten were evaluated following oral administration of an 8 mg/kg dose in Sprague Dawley rats and in a quantitative whole-body autoradiography study in Long Evans rats. [14C]Aficamten accounted for ∼80% and a hydroxylated metabolite (M1) accounted for ∼12% of total radioactivity in plasma over 48-h (AUC0–48). Plasma t max was 4-h and the t 1/2 of total plasma radioactivity was 5.8-h. Tissues showing highest Cmax exposures were myocardium and semitendinosus muscle. Most [14C]aficamten-derived radioactivity was excreted within 48-h post-administration. Mean cumulative recovery in urine and faeces over 168-h was 8.3% and 90.7%, respectively. In urine and bile, unchanged aficamten was detected at <0.1 and <0.2% of dose, respectively; however, based on total radioactivity excreted in urine (8.0%) and bile (51.7%), approximately 60% of dose was absorbed. [14C]Aficamten was metabolised by hydroxylation with subsequent glucuronidation where the most abundant metabolite recovered in bile was M5 (35.2%), the oxygen-linked glucuronide of hydroxylated aficamten (M1a). The major metabolite detected in faeces was a 1,2,4-oxadiazole moiety ring-cleaved metabolite (M18, 35.3%), shown to be formed from the metabolism of M5 in incubations with rat intestinal contents solution.

Radioactive ADME Demonstrates ARV-110's High Druggability Despite Low Oral Bioavailability.

Proteolysis-targeting chimeras (PROTACs) have emerged as potentially effective therapeutic medicines, but their high molecular weight and poor solubility directly impact their oral bioavailability. This work synthesized 14C-labeled bavdegalutamide (ARV-110) as a model compound of PROTACs to evaluate its ADME features. Compared with targeted antitumor drugs, the use of food increased oral bioavailability of ARV-110 in rats from 10.75% to 20.97%, which is still undesirable. However, the therapeutic effect of ARV-110 at a low dose was much better than that of enzalutamide, demonstrating the specific catalytic medicinal properties of PROTACs. Moreover, the specific distribution of ARV-110 in subcutaneous prostate tumors was determined by quantitative whole-body autoradiography (QWBA). Notably, the specificity and activity of PROTACs take precedence over their oral absorption, and high oral bioavailability is not necessary to produce excellent therapeutic effects. This work presents a roadmap for developing future PROTAC medications from a radioactive drug metabolism and pharmacokinetics (DMPK) perspective.

Metabolite analysis of 14C-labeled chloromethylisothiazolinone/methylisothiazolinone for toxicological consideration of inhaled isothiazolinone biocides in lungs

5-Chloro-2-methyl-4-isothiazolin-3-one (CMIT) and 2-methyl-4-isothiazolin-3-one (MIT) used as preservatives in various products, including humidifier disinfectants, presents substantial health hazards. This research delves into the toxicological assessments of CMIT/MIT in the respiratory system using animal models. Through the synthesis of radiolabeled [14C]CMIT and [14C]MIT, we investigated the biological uptake and in vivo behaviors of CMIT/MIT in the respiratory tissues following intratracheal exposure. Quantitative whole-body autoradiography (QWBA) revealed significant persistence of CMIT/MIT in lung tissue. In addition, radio high-performance liquid chromatography (radio-HPLC) with tandem mass spectrometry (LC-MS/MS) was employed for metabolite profiling and identification. Notably, around 28% of the radiolabel was retained in tissue after the extraction step, suggesting covalent binding of CMIT/MIT and their metabolites with pulmonary biomolecules. This observation demonstrates the propensity of the electrophilic isothiazolinone ring in CMIT/MIT to undergo chemical interactions with biothiols in proteins and enzymes, fostering irreversible alterations of biomolecules. Such accumulations of transformations could result in direct toxicity at both cellular and organ levels. Additionally, the detection of metabolites, including a MIT dimer conjugated with glutathione (GSH), as analyzed by mass spectrometry indicates the possible reduction of cellular GSH levels and subsequent oxidative stress. This investigation offers an in-depth insight into the toxic mechanisms of CMIT/MIT, underlying their capability to engage in complex formations with biomacromolecules and induce pronounced respiratory toxicity. These results highlight the imperative for stringent safety assessments of these chemicals, advocating for improved public health and safety measures in the use of chemicals.

Tissue distribution and retention drives efficacy of rapidly clearing VHL-based PROTACs

BackgroundProteolysis-targeting chimeras (PROTACs) are being developed for therapeutic use. However, they have poor pharmacokinetic profiles and their tissue distribution kinetics are not known.MethodsA typical von Hippel-Lindau tumor suppressor (VHL)—PROTAC 14C-A947 (BRM degrader)—was synthesized and its tissue distribution kinetics was studied by quantitative whole-body autoradiography (QWBA) and tissue excision in rats following IV dosing. Bile duct-cannulated (BDC) rats allowed the elucidation of in vivo clearance pathways. Distribution kinetics was evaluated in the tissues and tumors of mice to support PK-PD correlation. In vitro studies enabled the evaluation of cell uptake mechanisms and cell retention properties.ResultsHere, we show that A947 quickly distributes into rat tissues after IV dosing, where it accumulates and is retained in tissues such as the lung and liver although it undergoes fast clearance from circulation. Similar uptake/retention kinetics enable tumor growth inhibition over 2–3 weeks in a lung cancer model. A947 quickly excretes in the bile of rats. Solute carrier (SLC) transporters are involved in hepatocyte uptake of PROTACs. Sustained BRM protein degradation is seen after extensive washout that supports prolonged cell retention of A947 in NCI-H1944 cells. A947 tissue exposure and pharmacodynamics are inversely correlated in tumors.ConclusionsPlasma sampling for VHL-PROTAC does not represent the tissue concentrations necessary for efficacy. Understanding of tissue uptake and retention could enable less frequent IV administration to be used for therapeutic dosing.

From molecules to visuals: Empowering drug discovery and development with mass spectrometry imaging.

Over the past three decades, mass spectrometry imaging (MSI) has emerged as a valuable tool for the spatial localization of drugs and metabolites directly from tissue surfaces without the need for labels. MSI offers molecular specificity, making it increasingly popular in the pharmaceutical industry compared to conventional imaging techniques like quantitative whole-body autoradiography (QWBA) and immunohistochemistry, which are unable to distinguish parent drugs from metabolites. Across the industry, there has been a consistent uptake in the utilization of MSI to investigate drug and metabolite distribution patterns, and the integration of MSI with omics technologies in preclinical investigations. To continue the further adoption of MSI in drug discovery and development, we believe there are two key areas that need to be addressed. First, there is a need for accurate quantification of analytes from MSI distribution studies. Second, there is a need for increased interactions with regulatory agencies for guidance on the utility and incorporation of MSI techniques in regulatory filings. Ongoing efforts are being made to address these areas, and it is hoped that MSI will gain broader utilization within the industry, thereby becoming a critical ingredient in driving drug discovery and development.

Pharmacokinetic Study of Ultrasmall Superparamagnetic Iron Oxide Nanoparticles HY-088 in Rats.

HY-088 injection is an ultrasmall superparamagnetic iron oxide nanoparticle (USPIOs) composed of iron oxide crystals coated with polyacrylic acid (PAA) on the surface. The purpose of this study was to investigate the pharmacokinetics, tissue distribution, and mass balance of HY-088 injection. The pharmacokinetics of [55Fe]-HY-088 and [14C]-HY-088 were investigated in 48 SD rats by intravenous injection of 8.5 (low-dose group), 25.5 (medium-dose group), and 85 (high-dose group) mg/100 μCi/kg. Tissue distribution was studied by intravenous injection of 35 mg/100 μCi/kg in 48 SD rats, and its tissue distribution in vivo was obtained by ex vivo tissue assay. At the same time, [14C]-HY-088 was injected intravenously at a dose of 25.5 mg/100 μCi/kg into 16 SD rats, and its tissue distribution in vivo was studied by quantitative whole-body autoradiography. [14C]-HY-088 and [55Fe]-HY-088 were injected intravenously into 24 SD rats at a dose of 35 mg/100 μCi/kg, and their metabolism was observed. In the pharmacokinetic study, [55Fe]-HY-088 reached the maximum observed concentration (Cmax) at 0.08 h in the low- and medium-dose groups of SD rats. [14C]-HY-088 reached Cmax at 0.08 h in the three groups of SD rats. The area under the concentration-time curve (AUC) of [55Fe]-HY-088 and [14C]-HY-088 increased with increasing dose. In the tissue distribution study, [55Fe]-HY-088 and [14C]-HY-088 were primarily distributed in the liver, spleen, and lymph nodes of both female and male rats. In the mass balance study conducted over 57 days, the radioactive content of 55Fe from [55Fe]-HY-088 was primarily found in the carcass, accounting for 86.42±4.18% in females and 95.46±6.42% in males. The radioactive recovery rates of [14C]-HY-088 in the urine of female and male rats were 52.99±5.48% and 60.66±2.23%, respectively. Following single intravenous administration of [55Fe]-HY-088 and [14C]-HY-088 in SD rats, rapid absorption was observed. Both [55Fe]-HY-088 and [14C]-HY-088 were primarily distributed in the liver, spleen, and lymph nodes. During metabolism, the radioactivity of [55Fe]-HY-088 is mainly present in the carcass, whereas the 14C-labeled [14C]-HY-088 shell PAA is eliminated from the body mainly through the urine.

Unraveling Drug Safety: Importance of Toxicological Screening and Animal Models in Pharmacokinetics Studies for Clinical Medicinal Impact

The pharmacokinetics of a drug is an important factor in determining the safety of the drug. In this review, we focus on the importance of the toxicological screening and the methods using various animal models to determine any signs of toxicity in the drug substance. The toxicity data acquired is used to determine the relationship among the serum composition and the toxicity results, as well as their purpose and importance to the drug's clinical medicinal impacts. in silico models which generally utilize the help of computers study the parameters of ADME in an artificial environment and generally costlier model i.e., animal model is used in the later stages of testing of medications potency and hazards. In vitro studies are conducted in rats and are conducted firstly to offer data for different regions of body favoring pharmacological investigations. The radiation levels determined by quantitative whole-body autoradiography amongst various tissues at different point of time are important to study that why some compounds fail to exhibit favorable PK during preclinical ADME screening, this information could be immensely helpful to medicinal chemists for improvement of the weak backbones. Preclinical studies are modest, but they can become better if all the test procedure are followed in the right manner and right evidence is provided which highlights the desired biological effect at the same time risk assessment methods should also take place in case of any severe adverse effects.

Bioaccumulation and in vivo fate of toxic benzylalkyldimethylammonium chloride in rats via the radiotracer analysis

Benzylalkyldimethylammonium chloride (BAC), a quaternary ammonium compound (QAC), is utilized in industrial and biomedical applications for antimicrobial purposes. Since the coronavirus disease (COVID-19) outbreak, various types of BAC-containing household chemicals have been produced. BACs have several adverse effects; however, their biological uptake, translocation, and excretion in animal models (essential for better understanding in vivo behavior and toxicological impact) remain unclear. In this study, we performed the first biodistribution and whole-body imaging studies of BAC in male Sprague Dawley rats, using two different administration routes. Quantitative whole-body autoradiography (QWBA) data obtained for intranasal 14C-labeled BAC ([14C]C12-BAC) exposure showed substantial uptake values for the respiratory organs (e.g. 346 ng g−1 of lung at 3 h post administration) and the radiotracer was transported to other internal organs. The amount of radiotracer in the heart, adrenal gland, and pancreas were 198, 1410, and 186 ng g−1 tissue respectively at 168 h following exposure. Autoradiograms obtained after intravenous injection also showed high accumulation and slow excretion in these organs. The cumulative excretion analysis revealed that approximately 6.4% of the administered radioactivity remained in rats after a week. The results indicated that continuous inhalation exposure to BAC leads to potential toxic effects in extrapulmonary organs and the respiratory tract. Thus, the radiolabeling method utilized may help assess various synthetic QACs in living subjects.

Biodistribution of Lipid 5, mRNA, and Its Translated Protein Following Intravenous Administration of mRNA-Encapsulated Lipid Nanoparticles in Rats.

RNA-based therapeutics and vaccines represent a novel and expanding class of medicines, the success of which depends on the encapsulation and protection of mRNA molecules in lipid nanoparticle (LNP)-based carriers. With the development of mRNA-LNP modalities, which can incorporate xenobiotic constituents, extensive biodistribution analyses are necessary to better understand the factors that influence their in vivo exposure profiles. This study investigated the biodistribution of heptadecan-9-yl 8-((2-hydroxyethyl)(8-(nonyloxy)-8-] oxooctyl)amino)octanoate (Lipid 5)-a xenobiotic amino lipid- and its metabolites in male and female pigmented (Long-Evans) and nonpigmented (Sprague Dawley) rats by using quantitative whole-body autoradiography (QWBA) and liquid chromatography-tandem mass spectrometry (LC-MS/MS) techniques. After intravenous injection of Lipid 5-containing LNPs, 14C-containing Lipid 5 ([14C]Lipid 5) and radiolabeled metabolites ([14C]metabolites) were rapidly distributed, with peak concentrations reached within 1 hour in most tissues. After 10 hours, [14C]Lipid 5 and [14C]metabolites concentrated primarily in the urinary and digestive tracts. By 24 hours, [14C]Lipid 5 and [14C]metabolites were localized almost exclusively in the liver and intestines, with few or no concentrations detected in non-excretory systems, which is suggestive of hepatobiliary and renal clearance. [14C]Lipid 5 and [14C]metabolites were completely cleared within 168 hours (7 days). Biodistribution profiles were similar between QWBA and LC-MS/MS techniques, pigmented and nonpigmented rats, and male and female rats, excluding the reproductive organs. In conclusion, the rapid clearance through known excretory systems, with no evidence of redistribution for Lipid 5 or accumulation of [14C]metabolites, provides confidence for the safe and effective use of Lipid 5-containing LNPs. Significance Statement This study demonstrates the rapid, systemic distribution of intact and radiolabeled metabolites of Lipid 5, a xenobiotic amino lipid component of novel mRNA-LNP medicines, and its effective clearance without substantial redistribution after intravenous administration; additionally, findings were consistent between different mRNAs encapsulated within LNPs of similar composition. This study confirms the applicability of current analytical methods for lipid biodistribution analyses, and taken together with appropriate safety studies, supports the continued use of Lipid 5 in mRNA-medicines.

Assessment of the Pharmacokinetics, Disposition, and Duration of Action of the Tumour-Targeting Peptide CEND-1

CEND-1 (iRGD) is a bifunctional cyclic peptide that can modulate the solid tumour microenvironment, enhancing the delivery and therapeutic index of co-administered anti-cancer agents. This study explored CEND-1's pharmacokinetic (PK) properties pre-clinically and clinically, and assessed CEND-1 distribution, tumour selectivity and duration of action in pre-clinical tumour models. Its PK properties were assessed after intravenous infusion of CEND-1 at various doses in animals (mice, rats, dogs and monkeys) and patients with metastatic pancreatic cancer. To assess tissue disposition, [3H]-CEND-1 radioligand was administered intravenously to mice bearing orthotopic 4T1 mammary carcinoma, followed by tissue measurement using quantitative whole-body autoradiography or quantitative radioactivity analysis. The duration of the tumour-penetrating effect of CEND-1 was evaluated by assessing tumour accumulation of Evans blue and gadolinium-based contrast agents in hepatocellular carcinoma (HCC) mouse models. The plasma half-life was approximately 25 min in mice and 2 h in patients following intravenous administration of CEND-1. [3H]-CEND-1 localised to the tumour and several healthy tissues shortly after administration but was cleared from most healthy tissues by 3 h. Despite the rapid systemic clearance, tumours retained significant [3H]-CEND-1 several hours post-administration. In mice with HCC, the tumour penetration activity remained elevated for at least 24 h after the injection of a single dose of CEND-1. These results indicate a favourable in vivo PK profile of CEND-1 and a specific and sustained tumour homing and tumour penetrability. Taken together, these data suggest that even single injections of CEND-1 may elicit long-lasting tumour PK improvements for co-administered anti-cancer agents.

Investigational cyclin-dependent kinase 4/6 inhibitor GLR2007 demonstrates activity against isocitrate dehydrogenase wild-type glioblastoma and other solid tumors in mice xenograft models.

Cyclin-dependent kinases, CDK4 and CDK6, are essential in regulating the cell cycle, which is disrupted in cancers like isocitrate dehydrogenase wild-type glioblastoma (GBM). Currently marketed CDK4/6 inhibitors, including abemaciclib, have shown preclinical efficacy in solid tumors, but factors such as poor blood–brain barrier (BBB) penetration limit their efficacy in GBM. GLR2007 is an investigational CDK4/6 inhibitor with the potential for improved BBB penetration. In vitro assays were used to assess the potency and inhibition of CDK4/6 enzymatic activity of GLR2007. Using in vivo assays, the distribution of radiolabeled GLR2007 in rats was determined through quantitative whole-body autoradiography. The antitumor efficacy of GLR2007 was evaluated in human GBM and breast cancer orthotopic mice xenograft models, and human lung, colorectal, and liver cancer in a subcutaneous xenograft model. In tumor cell line proliferation assays, GLR2007 inhibited proliferation at lower concentration values than abemaciclib in 19 of 20 GBM, five of seven breast, 20 of 21 lung, and 24 of 24 liver cancer cell lines. Total levels of radiolabeled GLR2007 in the brains of rats exceeded those in plasma by 2.3–4.5-fold from 2–6 hours after dosing. A xenograft model showed that, compared with vehicle control, 50 mg/kg GLR2007 induced 95.9% tumor growth inhibition (TGI) (P<0.001) in GBM orthotopic xenografts, 81.4% TGI (P=0.037) in breast cancer orthotopic xenografts, and 91.5% TGI (P<0.001) in colorectal cancer subcutaneous xenografts. These studies show possible BBB penetration of GLR2007 and demonstrate its potential as a CDK4/6 inhibitor for the treatment of solid tumors, including GBM.

Tissue Distribution of [14C]-Lefamulin into the Urogenital Tract in Rats.

ABSTRACTLefamulin, a semisynthetic pleuromutilin antibiotic approved in the United States, Canada, and Europe for intravenous and oral treatment of community-acquired bacterial pneumonia, is highly active in vitro against bacterial pathogens that cause sexually transmitted infections (STIs), including multidrug-resistant strains of Neisseria gonorrhoeae, Chlamydia trachomatis, and Mycoplasma genitalium. This nonclinical study used quantitative whole-body autoradiography (QWBA) and qualitative tape-transfer microautoradiography (MARG) to investigate lefamulin distribution into urogenital tract tissues down to a cellular level in male and female rats. A single intravenous dose (30 mg/kg) of [14C]-lefamulin was administered to 3 male and 3 female Sprague-Dawley rats. At 0.5, 6, and 24 h post dose, rats were euthanized and [14C]-lefamulin distribution was investigated using QWBA and MARG of sagittal planes. [14C]-lefamulin was well distributed throughout the carcasses of male and female rats, with the highest concentrations observed in male bulbourethral gland, urethra, prostate in female clitoral gland, uterus (particularly endometrium), and ovary. In these areas, concentrations were similar to or higher than those observed in the lungs. Concentrations peaked at 0.5 h post dose, remaining detectable in the urogenital tract up to 24 h post dose. [14C]-lefamulin in rats showed rapid, homogeneous distribution into urogenital tissues down to a cellular level, with high tissue:blood ratios in tissues relevant to STI treatment. These results, and the potent in vitro activity of lefamulin against multidrug-resistant bacteria known to cause STIs, will help inform further assessment of lefamulin, including potential clinical evaluation for treatment of STIs.

Comparison of the Tissue Distribution of a Long-Circulating Glucagon-like Peptide-1 Agonist Determined by Positron Emission Tomography and Quantitative Whole-Body Autoradiography.

Positron emission tomography (PET) is a molecular imaging modality that enables non-invasive visualization of tracer distribution and pharmacology. Recently, peptides with long half-lives allowed once-a-week dosing of glucagon-like peptide-1 receptor (GLP-1R) agonists with therapeutic applications in diabetes and obesity. PET imaging for such long-lived peptides is hindered by the typically used short-lived radionuclides. Zirconium-89 (89Zr) emerged as a promising PET radionuclide with a sufficiently long half-life to be applied for biodistribution studies of long-circulating biomolecules. A comparison between the biodistribution profiles obtained via 89Zr-PET and the current standard, quantitative whole-body autoradiography (QWBA), will be valuable for the development of novel peptide drugs. We determined the PET biodistribution of a 89Zr-labeled acylated peptide agonist of GLP-1R and compared it to the profile obtained by QWBA using analogous tritiated tracers for up to 1 week after administration. The plasma metabolic profile was obtained and identification was done for the tritiated tracers. We found that, at early time points, the biodistribution profiles agreed between PET and QWBA. At the latertime points, the 89Zr tracer remained primarily trapped in the kidneys. The introduction of desferrioxamine (DFO) chelator reduced the peptide stability, and UPLC-MS analysis identified a circulating metabolite arising from DFO hydrolysis. Kidney accumulation of radiolabeled peptides and DFO metabolic instability may compromise biodistribution studies using 89Zr-PET to support the development of new biopharmaceuticals. PET and QWBA biodistribution data correlated well during the absorption phase, but new and more stable 89Zr chelators are needed for a more accurate description of the elimination phase.

Pharmacokinetics, Mass Balance, Excretion, and Tissue Distribution of Plasmalogen Precursor PPI-1011.

PPI-1011 is a synthetic plasmalogen precursor in development as a treatment for multiple plasmalogen-deficiency disorders. Previous work has demonstrated the ability of PPI-1011 to augment plasmalogens and its effects in vitro and in vivo, however, the precise uptake and distribution across tissues in vivo has not been investigated. The purpose of this study was to evaluate the pharmacokinetics, mass balance, and excretion of [14C]PPI-1011 following a single oral administration at 100 mg/kg in Sprague-Dawley rats. Further tissue distribution was examined using quantitative whole-body autoradiography after both single and repeat daily doses at 100 mg/kg/day. Non-compartmental analysis showed that following a single dose, PPI-1011 exhibited peak levels between 6 and 12 h but also a long half-life with mean t1/2 of 40 h. Mass balance showed that over 50% of the compound-associated radioactivity was absorbed by the body, while approximately 40% was excreted in the feces, 2.5% in the urine, and 10% in expired air within the first 24 h. Quantitative whole-body autoradiography following a single dose showed uptake to nearly all tissues, with the greatest initial uptake in the intestines, liver, and adipose tissue, which decreased time-dependently throughout 168 h post-dose. Following 15 consecutive daily doses, uptake was significantly higher across the entire body at 24 h compared to single dose and remained high out to 96 h where 75% of the initially-absorbed compound-associated radioactivity was still present. The adipose tissue remained particularly high, suggesting a possible reserve of either plasmalogens or alkyl diacylglycerols that the body can pull from for plasmalogen biosynthesis. Uptake to the brain was also definitively confirmed, proving PPI-1011’s ability to cross the blood-brain barrier. In conclusion, our results suggest that oral administration of PPI-1011 results in high uptake across the body, and that repeated dosing over time represents a viable therapeutic strategy for treating plasmalogen deficiencies.

An Effective QWBA/UHPLC-MS/Tissue Punch Approach: Solving a Pharmacokinetic Issue via Quantitative Met-ID.

Methods to provide absolute quantitation of the administered drug and corresponding metabolites in tissue in a spatially resolved manner is a challenging but much needed capability in pharmaceutical research. Quantitative Whole-Body Autoradiography (QWBA) after a single- dose intravenous (3 mg/kg) and extravascular (30 mg/kg) administrations of an in vitro metabolically stable test compound (structure not reported here) indicated quick tissue distribution and excretion. Good bioavailability and short in vivo half-lives were determined formerly for the same test compound. For closing gaps in the understanding of pharmacokinetic data and in vitro results, radioactive hot spots on whole-body tissue sections had been profiled. Punches from selected tissue regions containing high radioactivity in the tissue sections previously analyzed by QWBA were extracted by a highly organic solvent and analyzed without any consecutive sample preparation step, applying Ultra High Performance Liquid Chromatography- Mass Spectrometry (UHPLC-MS) and off-line radioanalysis to maximize signal levels for metabolite identification and profiling. The analysis revealed that the test compound was metabolized intensively by phase I reactions in vivo and the metabolites formed were excreted in bile and urine. The predominant metabolites showed abundant signal intensities both by MS and by radioanalysis but the MS signal intensities generally underestimated the real abundances of metabolites relative to the unchanged drug. This work illustrates that maximizing the sensitivity of tissue punch radioanalysis and the combination with UHPLC-MS leads to a better insight into pharmacokinetic processes by providing quantitative data with high molecular selectivity.

EXTH-14. PRECLINICAL EVALUATION OF NOVEL CDK4/6 INHIBITOR GLR2007 IN GLIOBLASTOMA MODELS

Abstract Glioblastoma multiforme (GBM) is characterized by a high frequency of cyclin-dependent kinase (CDK)4 and CDK6 pathway dysregulation. None of the approved CDK4/6 inhibitors are indicated for GBM. Poor blood–brain barrier (BBB) penetration is a potential factor limiting treatment efficacy in GBM. GLR2007 is an investigational CDK4/6 inhibitor with the potential for improved penetration across the BBB. These preclinical studies investigated the anti-tumor efficacy in GBM xenograft models and central nervous system distribution of GLR2007. In vivo evaluation of the anti-tumor efficacy of GLR2007 versus vehicle, abemaciclib, and/or palbociclib was performed in two BALB/c nude mouse GBM xenograft models. Efficacy was expressed as tumor growth inhibition (TGI, change in mean tumor volume from baseline as a percentage of change in vehicle group) or increased survival time. Following 21 days of treatment, TGI in BN2289 subcutaneous xenografts was 39.4% and 56.4% for 25 mg/kg and 50 mg/kg GLR2007 groups, respectively, 34.0% for 25 mg/kg palbociclib, and 24.9% for 25 mg/kg abemaciclib (p &amp;lt; 0.001 in all groups vs vehicle control). In U87-luc orthotopic xenografts, compared with vehicle controls, median survival time was 50.0% (p = 0.0009) longer in the 12.5 mg/kg GLR2007 group, similar to the 150 mg/kg abemaciclib group (54.4%, p = 0.0002), and was 182.6% (p &amp;lt; 0.0001) longer in mice treated with 50 mg/kg GLR2007. Quantitative whole-body autoradiography was used to determine the distribution of [14C]GLR2007 in Sprague Dawley rats following a single oral dose. Total radioactivity levels in the brain exceeded those in plasma by 2.3–4.5-fold from 2–6 h after dosing. These preclinical studies suggest the potential of GLR2007 for the treatment of GBM, supported by evidence that GLR2007 showed numerically greater anti-tumor efficacy than approved CDK4/6 inhibitors palbociclib and abemaciclib in GBM xenograft models, and evidence of substantial central nervous system distribution.

Siponimod (BAF312) penetrates, distributes, and acts in the central nervous system: Preclinical insights.

BackgroundSiponimod (BAF312), a selective S1P1/S1P5 agonist, reduces disability progression in secondary progressive MS. Recent observations suggest it could act via S1P1/S1P5-dependent anti-inflammatory and pro-myelination effects on CNS-resident cells.ObjectiveGenerate preclinical evidence confirming siponimod's CNS penetration and activity.MethodsSiponimod's CNS penetration and distribution was explored in rodents and non-human primates (NHPs) using: Liquid Chromatography coupled to tandem Mass Spectrometry (LC-MS/MS), quantitative whole-body autoradiography (QWBA) using 14C-radiolabeled siponimod or non-invasive single-photon emission CT (SPECT) with a validated 123I-radiolabeled siponimod analog. Functional CNS activity was investigated by S1P1 receptor quantification in brain homogenates.ResultsIn mice/rats, siponimod treatments achieved dose-dependent efficacy and dose-proportional increase in drug blood levels, with mean brain/blood drug-exposure ratio (Brain/BloodDER) of 6–7. Efficacy in rat brain tissues was revealed by a dose-dependent reduction in brain S1P1 levels. QWBA distribution analysis in rats indicated that [14C]siponimod related radioactivity could readily penetrate CNS, with particularly high uptakes in white matter of cerebellum, corpus callosum, and medulla oblongata versus lower exposures in other areas such as olfactory bulb. SPECT monitoring in NHPs revealed CNS distribution with a brain/bloodDER of ∼6, as in rodents.ConclusionFindings demonstrate siponimod's CNS penetration and distribution across species, with high translational potential to human.

Abstract 1370: ADME and toxicology profiles of first-in-class DRD2/ClpP-targeted imipridone ONC201

Abstract Imipridone ONC201 is a first-in-class DRD2 antagonist and ClpP agonist that is well tolerated and induces durable tumor regressions in H3 K27M-mutant glioma patients with once weekly dosing. We evaluated the toxicology, absorption, distribution, metabolism and excretion of ONC201 in animals. Repeat-dose 28-day studies with weekly oral ONC201 in rats and dogs revealed NOAELs (75 and 60 mg/kg, respectively) that represent higher dose levels compared to the 625 mg clinical dose. Genotoxicity (AMES, in vitro and in vivo micronucleus assays) assays demonstrated that ONC201 is not mutagenic at exposures above the RP2D and 2µM average Cmax in patients. The 3T3 neural red uptake assay showed ONC201 is not a phototoxin (photo-irritant factor 1.1). In embryofetal development studies, ONC201 did not lead to maternal effects in rats or rabbits and caused fetal malformations in 3/61 rabbit fetuses with daily dosing (from gestation day 7-17 or 19) at 62.5 and 25 mg/kg, respectively. A quantitative whole-body autoradiography study conducted in rats with one dose of [14C]-ONC201 showed rapidly tissue distribution peaking at 1h in most tissues and exhibiting a plasma terminal half-life of 5.6h. The endocrine, metabolic/excretory, ocular and GI tract tissues contained the highest distribution of [14C]ONC201. [14C]-ONC201 was distributed evenly across CNS substructures, including the midline region. Consistent with the uniform distribution, ONC201 displayed high permeability (23-31×10-6 cm/s, 7-700 μM) and was not a substrate of efflux transporters in Caco-2 cells (efflux ratio 0.46-0.79). ONC201 exerted inhibitory potential on MDR1- and BCRP-mediated transport at 200μM. Clinical trials with ONC201 restrict use of concomitant medications that induce or inhibit CYP enzymes, but several supportive medications can affect these enzymes. In vitro studies revealed that ONC201 is not an inducer of 7 major human CYP enzymes but does inhibit and is a substrate of CYP 2B6, 2C8, 2C9, 2C19, 2D6 and 3A4 (IC50 20-90µM). Analysis of dexamethasone, a known inducer of CYP3A4, did not show a correlation between baseline dose level and ONC201 plasma concentrations in H3 K27M-mutant glioma patients (n=22). Metabolic profiling in human hepatocytes revealed only one metabolite, ONC207, that was &amp;gt;10% in abundance. ONC207 did not achieve an IC50 in cancer cell viability and DRD2 antagonism assays. Assaying by LC-MS/MS of plasma samples obtained from ONC201-treated H3 K27M-mutant glioma patients (n=20) confirmed the presence of ONC207 as the major metabolite. A mass balance study conducted in rats with one dose of [14C]-ONC201 showed that the main route of excretion was biliary (61.18%) via the feces (69.78%), with urine (24.99%) also contributing to overall recovery. Together, these data inform the administration of ONC201 to advanced cancer patients who often require a range of comedications and comorbidities. Citation Format: Sara Morrow, Rohinton Tarapore, Ailan Guo, Magdalena Nej, Yunlan Fang, Gina Theerman, Leah Lake, Martin Stogniew, Varun V. Prabhu, Joshua E. Allen. ADME and toxicology profiles of first-in-class DRD2/ClpP-targeted imipridone ONC201 [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 1370.

Excretion and Distribution of the 60-kDa PEG Moiety Used in BAY 94-9027 in Male Wistar Rats

Introduction: PEGylation is a widely used method to prolong the half-life of therapeutic proteins. Long-acting factor VIII (FVIII) products developed through PEGylation may potentially reduce the burden associated with prophylaxis in patients with hemophilia A. BAY 94-9027 is a prolonged-half-life FVIII product modified through site-specific addition of a 60-kDa (2 × 30-kDa branched) PEG via a maleimide linker to a cysteine amino acid. BAY 1025662 is the 60-kDa PEG moiety used for PEGylation including linker and cysteine (PEG-60-Mal-Cys). In toxicology studies, BAY 94-9027 and BAY 1025662 were not associated with any adverse events or PEG-related cellular vacuolation (Ivens et al. Haemophilia. 2013;19:11-20). The rate-limiting clearance of the PEG part of PEGylated proteins after metabolism is expected to be similar to that when the corresponding PEG is administered alone (Baumann et al. Drug Discov Today . 2014;19:1623-1631). The study objective was to investigate the pharmacokinetics and mass balance of total radioactivity in male Wistar rats after a single intravenous (IV) administration of [14C]-labeled BAY 1025662, including size exclusion chromatography profiles of urine at selected time points.Methods: Radiolabeled BAY 1025662 ([prop-14C]BAY 1025662) was synthesized using a 2-step process resulting in a maleimide linker bearing the [14C] label at the propionic acid moiety. Radioactivity following a single IV dose of 11 mg/kg (the estimated maximal human PEG dose over ~30 years' treatment with BAY 94-9027) was determined in body fluids, organs and tissues, and in excreta by liquid scintillation counting after appropriate sample preparation and by quantitative whole-body autoradiography during and at the end of the study.Results: Single-dose mass balance studies using [prop-14C]BAY 1025662 showed that 30.4% of administered radioactivity was excreted within 1 week (23.7% in urine and 6.3% in feces); cumulative excretion at day 168 via urine and feces was 82.6% of the administered dose (68.4% via urine, 13.8% via feces). High-performance liquid chromatography profiling analysis of rat urine suggested that BAY 1025662 is excreted nearly unchanged (74% of total radioactivity, corresponding to 17.6% of dose, present unchanged in urine in the 0- to 168-hour interval). Radioactivity was continuously, albeit slowly, eliminated throughout the study; elimination half-life was 23 and 24 days in blood and plasma, respectively. The corresponding elimination half-lives of radioactivity were 33, 31, 39, 54, and 68 days in the liver, skin, carcass, testes, and kidneys, respectively. Elimination was almost complete at the end of experiment, with a total recovery of radioactivity (cumulative excretion plus residues in animals) of 89% on day 168. Following [prop-14C]BAY 1025662 administration, radioactivity was slowly distributed from blood to peripheral organs, reaching maximum concentration 2 hours postdose; highest maximum concentration was observed in blood, followed by lung and liver. At day 168, only ~4% of the administered radioactive dose was still present in the animal body, partially localized in endocrine/exocrine glands and lymphatic organs. No residual radioactivity was observed in the brain, indicating no crossing of the blood-brain barrier.Conclusions: Following single-dose administration of [prop-14C]BAY 1025662, elimination was almost complete by the end of the experiment on day 168. These results suggest that there are excretion processes in place for high-molecular-weight PEGs such as the PEG 60 moiety used in BAY 94-9027. Two clearance processes are proposed for large PEGs (>30 kDa), as indicated by a faster initial excretion over the first 1-2 weeks, followed by a nonspecific uptake into cells by pinocytosis leading to a longer elimination half-life. The PEG moiety can be recycled from inside the cells back to the plasma, possibly by exocytosis, to then undergo further (mainly renal) excretion (Baumann et al. Drug Discov Today . 2014;19:1623-1631). DisclosuresBaumann:Bayer AG: Employment. Schwarz:Bayer AG: Employment. Hucke:Bayer AG: Employment. Piel:Bayer AG: Employment. Sandmann:Bayer AG: Employment.