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Over the past two decades, we have seen an increase in the complexity and diversity of biotherapeutic modalities pursued by biopharmaceutical companies. These biologics are multifaceted and susceptible to post-translational modifications and in vivo biotransformation that could impose challenges for bioanalysis. It is vital to characterize the functionality, stability and biotransformation products of these molecules

The term “bioanalytical” encompasses a much greater breadth of analytical deliverables than ever before. Circulating drug concentration data are complemented by experimental evidence of drug in biophase, immunogenicity, target engagement and subsequent pathway modulation. Many bioanalytical assays bridge the traditional divide across discovery and development. Our approach is the Bioanalytical Hub model bringing together a

Scientifically qualified LC–MS/MS methods are essential for the determination of small molecule drug candidates and/or their metabolite(s) in support of various non-regulated safety assessment and in vivo absorption, distribution, metabolism and excretion studies in preclinical development. This article outlines an effective method development workflow to fit for this purpose. The workflow features a ‘universal’ protein

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Aim: To perform an exposure assessment of arsenic, manganese, mercury and lead levels in hair samples from children from poor neighborhoods. Materials & methods: A total of 38 Caucasian children were recruited with the consent of their parents or tutors. Determinations were performed by atomic absorption spectrometry. Results & conclusion: Results were 0.045–0.12 μg/g-1 (arsenic),

Aim: RBD1016 is an N-acetylgalactosamine-conjugated siRNA drug currently in a phase II trial for treatment of chronic hepatitis B virus. To evaluate its absorption, distribution, metabolism and excretion (ADME) and pharmacokinetic/pharmacodynamic (PK/PD) properties, two LC-based bioanalytical methods, LC–high-resolution/accuracy MS and LC–fluorescence detection, were developed and qualified. Materials & methods: The LC–high-resolution/accuracy MS method was used

Aim: Tetrahydrobiopterin (BH4), a natural cofactor of aromatic amino acid hydroxylases, and sepiapterin, a natural precursor of BH4, are endogenously present in human plasma. This is the first report on methods for direct quantification of sepiapterin and BH4 in human plasma by LC–MS/MS for pharmacokinetic assessment. Materials & methods: The analytes in plasma were harvested

Background: The authors report the relevance of using a point of care test (Helge®) for free hemoglobin determination and concordance of the values the with Cobas® 8000 and spectrophotometer methods. Results: The within-run of the point of care test was <3%. Good correlations among the three methods were observed and an acceptable concordance for hemolysis

Min Meng received her PhD in biomedicinal chemistry from the School of Pharmacy, University of Maryland, in 1996. From 1996 to 1998, Meng was a postdoctoral fellow at the American Health Foundation, focusing on the carcinogenic toxicity of tobacco smoke using various chromatographic technologies such as LC-UV, GC-MS/MS and LC–MS/MS. From 1998 to 2017, Meng