Validation and life-cycle management of a quantitative ligand-binding assay for the measurement of Nulojix(®), a CTLA-4-Fc fusion protein, in renal and liver transplant patients.

BACKGROUND: Nulojix(®) is a fusion protein composed of the Fc portion of a human IgG1 linked to the extracellular modified domain of CTLA-4. Nulojix differs from another Bristol Myers Squibb product, Orencia(®) by two amino acids and was approved by the FDA on 15 June 2011 for the prophylaxis of organ rejection in adult patients receiving kidney transplant. RESULTS: A sandwich ELISA utilizing two monoclonal antibodies against CTLA-4 was employed for Nulojix quantification and pharmacokinetic analysis. At least 17 analysts have qualified on the assay and contributed to reportable results over the last 7 years. In-study accuracy and precision demonstrate suitable performance: %bias within -4 to 4%, %CV ≤13% and total error within 6-15%. Incurred sample reanalysis was completed in applicable disease-state populations. The assay was automated and validated in additional clinical matrices (ascites and urine) and Nulojix quantification was validated in the presence of clinically relevant co-administered compounds. In 2011, the biotinylation procedure was modified meriting a regression change (quadratic to 4-parameter logistic) and associated partial validation. CONCLUSION: This long-term pharmacokinetic program provides a good example of the dynamic clinical environment and adaptation requirements of ligand-binding assays.

Biotherapeutic bioanalysis: a multi-indication case study review.

A thorough understanding of the structure and biology of a biotherapeutic is crucial to defining a suitable strategy for pharmacokinetic characterization in proof-of-concept disease models, toxicology species as well as the healthy and disease indication patient populations. This manuscript summarizes parameters that impact bioanalytical strategy for over 50 biotherapeutics indicated for the treatment of oncology, rheumatoid arthritis, allergy, multiple sclerosis, hematology, metabolism and infectious disease. We have addressed numerous therapeutic modalities including chimeric, humanized and fully human monoclonal antibodies, replacement proteins, peptides and fusion proteins, including polyethylene glycol and Fc fusions, as well as antibody-drug conjugates. With the rapid evolution of biotherapeutics over the last 20 years and the contraction of the pharmaceutical and biotechnology labor force, efficient workflow management becomes a crucial bioanalytical component. Thus, we have also addressed new technologies that have demonstrated either increased throughput or enhanced characterization, including Meso Scale Discovery, Gyrolab and affinity MS.

Troubleshooting PEG-hGH detection supporting pharmacokinetic evaluation in growth hormone deficient patients.

INTRODUCTION: The ability to quantify systemic concentrations of protein therapeutics is complicated by the presence of endogenous analyte, specific binding proteins, and nonspecific matrix components in biological matrices (Lee & Ma, 2007). Further complications can be introduced following pegylation whereby polyethylene glycol (PEG) impedes epitope recognition. Due to substantial interference from high affinity binding proteins and the inability to measure systemic drug concentrations under normal conditions, acid dissociation was implemented to facilitate the pharmacokinetic evaluation of clinical samples containing pegylated human growth hormone (PEG-hGH). METHODS: A sandwich electrochemiluminescent immunosorbent assay (ECLA) was employed using an anti-PEG capture, anti-hGH detection format, thereby eliminating cross-reactivity with endogenous compound. Samples were acid treated with glycine buffered hydrochloric acid (approximately pH 2.0) to dissociate PEG-hGH from serum resident growth hormone binding protein (GHBP; 3). After neutralization with a HEPES-based neutralizing buffer, samples were diluted in a casein-based assay buffer containing 0.2% I-block, 0.1% Tween-20, 2M NaCl, and 10% normal mouse serum to eliminate nonspecific matrix effects. Meso Scale Discovery (MSD) technology was employed to achieve sensitivity requirements. RESULTS: The drug detection assay was validated in the presence and absence of acid dissociation. Validation parameters included: intra- and inter-assay accuracy and precision, selectivity (>60 lots of normal and growth hormone deficient human serum), cross-reactivity/specificity (Genotropin, hemoglobin, lipid, and bilirubin), dilutional linearity and stability (DeSilva et al., 2003; Shah et al., 1992; Smolec et al., 2005 Viswanathan et al., 2007; Food and Drug Administration, 2001). A 10-fold molar excess of GHBP was found to decrease PEG-hGH detection by >90% while acid dissociation was shown to recover >80% of the analyte. PEG-hGH clinical pharmacokinetic samples were analyzed with and without acid treatment. Only 38% of the mid-dose samples were quantifiable without acid treatment while 92% were quantifiable after acid dissociation. DISCUSSION: The implementation of acid dissociation was found to substantially increase the number of quantifiable pharmacokinetic samples over the drug exposure time course and contributed significantly to the robustness of pharmacokinetic evaluation.

Novel heparanase-inhibiting antibody reduces neointima formation.

Basic fibroblast growth factor (bFGF), stored bound to heparan sulfate proteoglycans in the extracellular matrix (ECM) of the arterial media, may initiate smooth muscle cell (SMC) proliferation after coronary intervention, thus contributing to restenosis. bFGF mobilization from ECM stores after injury may be induced by platelet degranulation products such as heparanase. Therapies aimed at the inhibition of bFGF release and activation may assist in prevention of restenosis. To test this theory, we first examined the mobilization and activation of bFGF in the arterial media by platelet-derived heparanase. Heparanase, locally delivered to the rat carotid artery, was found to release bFGF and induce substantial SMC proliferation in the absence of actual vascular injury. An antibody that neutralizes heparanase was then developed and evaluated in a rat carotid balloon injury model. Local delivery of anti-heparanase IgG was found to inhibit bFGF release by approximately 60% ( p < 0.001) at 4 d; this correlated with the significant reduction in neointima formation observed at 14 d (intimal area/medial area: control 1.3 +/- 0.3, anti-heparanase 0.35 +/- 0.12, p < 0.0001). Platelet-derived heparanase is therefore likely to be important in initiating events leading to restenosis via bFGF mobilization. Furthermore, heparanase neutralization may assist in the prevention of restenosis following vascular injury.

Nitric oxide-generating hydrogels inhibit neointima formation.

This study evaluated the effects of localized delivery of nitric oxide (NO) from hydrogels covalently modified with S-nitrosocysteine (Cys-NO) on neoinitma formation, a key component of restenosis, in a rat balloon-injury model. Soluble Cys-NO was used in preliminary studies to identify dosage ranges that were able to simultaneously inhibit smooth muscle cell proliferation, enhance endothelial cell proliferation, and reduce platelet adhesion. Photo-cross-linked PEG-based hydrogels were formed with covalently immobilized Cys-NO. These materials release NO for approximately 24 h and can be applied to tissues and photo-cross-linked in situ to form local drug-delivery systems. Localized delivery of NO from hydrogels containing Cys-NO inhibited neointima formation in a rat balloon-injury model by approximately 75% at 14 days.

Heparanase and platelet factor-4 induce smooth muscle cell proliferation and migration via bFGF release from the ECM.

Basic fibroblast growth factor (bFGF) has been shown to play an instrumental role in the cascade of events leading to restenosis; however, the mechanisms of bFGF activation following vascular injury have remained elusive. We have demonstrated that heparanase and platelet factor-4 (PF4), released from activated platelets at the site of injury, liberate bFGF from the extracellular matrix (ECM) of vascular smooth muscle cells (SMC), resulting in the induction of SMC proliferation and migration. Increases in proliferation and migration were inhibited by treatment with a bFGF-neutralizing antibody, suggesting that proliferation and migration in response to heparanase or PF4 are mediated by bFGF activation. When platelets were seeded on top of SMCs, degranulation products were found to release bFGF from the ECM, increasing cell proliferation and cell migration. Again, these increases in SMC proliferation and migration were inhibited by treatment with an anti-bFGF antibody. Furthermore, these increases in proliferation were completely inhibited by treatment with an anti-heparanase antibody. Platelet degranulation products, such as heparanase and PF4, may liberate bFGF from extracellular sequestration, activating the growth factor and inducing the SMC proliferation and migration that contribute to the wound healing response following vascular injury.