An Interlaboratory Study to Identify Potential Visible Protein-Like Particle Standards.

Visible protein-like particle standards may improve visual inspection and/or appearance testing practices used in the biotechnology industry. They may improve assay performance resulting in better alignment and more standardized training among different companies. The National Institute of Standards and Technology (NIST) has conducted an interlaboratory study to test whether the standards under development mimic typical proteinaceous particles found in biotherapeutics and if they can be implemented during the visual inspection process. Fourteen organizations from industry and government have participated. A total of 20 labs from these 14 organizations participated with analysts from 6 formulation, 7 analytical, 4 quality control, and 3 manufacturing labs. The circulated samples consisted of abraded ethylene tetrafluoroethylene (ETFE) particles or photolithographic particles. The results consist of qualitative ratings, which varied substantially among organizations and within labs. Polydisperse ETFE particle suspensions, containing particles enriched in greater than 150 µm in size, were rated more favorably than the photolithographic particles by formulation and analytical scientists. The largest monodisperse photolithographic particles (approximately 300 µm in size) were favored equally compared to ETFE by all scientists. Solution modifications to decrease the settling rate or to alter optical properties of the ETFE solutions yielded lower ratings by the analysts. Both particle types received mixed ratings for their usability and for their application for visual inspection and for training purposes. Industry feedback will assist NIST in developing reference material(s) for visible protein-like particles.

lmplementation of the prolyl hydroxylase inhibitor Roxadustat (FG-4592) and its main metabolites into routine doping controls.

The utility of hypoxia-inducible factor (HIF) prolyl hydroxylase inhibitors as a therapeutic means of treating patients suffering from anaemia has been demonstrated for various clinical settings. However, besides this intended use, HIF stabilizers can be the subject of misuse in amateur and elite sports due to their erythropoietic properties, as recently proven by several cases of adverse analytical findings in doping control testing. Consequently, to allow for adequate and comprehensive test methods, knowledge of the drug candidates' metabolism and analytical options enabling appropriate detection windows in sports drug testing samples (i.e., blood and urine) is essential to doping control laboratories. In the present study, a novel HIF prolyl hydroxylase inhibitor referred to as Roxadustat (FG-4592) and main plasma- and urine-derived metabolites were investigated in the context of routine doping control analytical approaches. Liquid chromatography-mass spectrometry-based test methods were used to study the target analytes' dissociation pathways following electrospray ionization and collision-induced dissociation. Diagnostic precursor-product ion pairs were selected to enable the implementation of the intact drug Roxadustat and selected metabolites into multi-analyte initial testing procedures for plasma and urine specimens. The assays were validated in accordance to guidelines of the World Anti-Doping Agency (WADA) and results demonstrated the suitability (fitness-for-purpose) of the employed analytical methods with detection limits ranging from 0.05 to 1 ng/mL and 1 to 5 ng/mL for urine and plasma, respectively. Subsequently, elimination study plasma and urine samples collected up to 167 h post-administration were analyzed using the validated methods, which suggested the use of different target analytes for blood and urine analyses with FG-4592 and its glucuronide, respectively, for optimal detection windows. Additionally, a light-induced rearrangement product (photoisomer) of Roxadustat resulted in the formation of an additional compound of identical mass. Copyright © 2017 John Wiley & Sons, Ltd.

Recombinant collagen and gelatin for drug delivery.

The tools of recombinant protein expression are now being used to provide recombinant sources of both collagen and gelatin. The primary focus of this review is to discuss alternatives to bovine collagen for biomedical applications. Several recombinant systems have been developed for production of human sequence collagens. Mammalian and insect cells were initially used, but were thought to be too costly for commercial production. Yeast have been engineered to express high levels of type I homotrimer and heterotrimer and type II and type III collagen. Co-expression of collagen genes and cDNAs encoding the subunits of prolyl hydroxylase has lead to the synthesis of completely hydroxylated, thermostable collagens. Human types I and III collagen homotrimers have been expressed in transgenic tobacco plants, while transgenic mice have been engineered to produce full-length type I procollagen homotrimer as well as a alpha2 (I) homotrimeric mini-collagen. Most recently, a transgenic silkworm system was used to produce a fusion protein containing a collagenous sequence. Each of these transgenic systems holds great promise for the cost-effective large-scale production of recombinant human collagens. As seen in other recombinant expression systems, transgenic silkworms, tobacco, and mice lack sufficient endogenous prolyl hydroxylase activity to produce fully hydroxylated collagen. In mice and tobacco, this was overcome by over-expression of prolyl hydroxylase, analogous to what has been done in yeast and insect cell culture. In addition to recombinant alternatives to bovine collagen, other sources such as fish and sponge collagen are discussed briefly. Recombinant gelatin has been expressed in Pichia pastoris and Hansenula polymorpha in both non-hydroxylated and hydroxylated forms. Pichia was shown to be a highly productive system for gelatin production. The recombinant gelatins produced in yeast are of defined molecular weight and physio-chemical properties and represent a new biomaterial not previously available from animal sources. Genetic engineering has made great progress in the areas of recombinant collagen and gelatin expression, and there are now several alternatives to bovine material that offer an enhanced safety profile, greater reproducibility and quality, and the ability of these materials to be tailored to enhance product performance.

Photosensitizers form in histidine buffer and mediate the photodegradation of a monoclonal antibody.

Fluorescent light (FL) photodegradation of a monoclonal antibody (mAb) formulated in histidine buffer is mediated by histidine-derived photosensitizers that accumulate and greatly increase with light exposure. Histidine-derived photosensitizers are the primary mediators of Trp photooxidation. FL-photodegradation requires light exposure and is pH dependent. It is significantly reduced or eliminated by buffer exchanges, by oxygen depletion, or at pH values greater than 7. Antibody-fragment MS ion counts reveal that oxidation of a single light chain Trp in CDR1 correlates with binding loss. Multiple heavy chain methionines oxidize, but poorly correlate with binding loss. Photosensitizers extracted from photo-aged histidine buffer are potent mediators of FL-photodegradation including oxidation and, to a lesser degree, fragmentation and aggregation of the mAb. These photosensitizers absorb visible light and have neutral mass of 187.1- 386.1 Da. They are also fluorescent with ex/em at 360/450 nm. When spiked into histidine or MES buffered mAb formulations they produce a concentration dependent and pronounced increase in FL-photodegradation; however, no oxidation or loss of antibody function occurs in the dark and hydrogen peroxide does not oxidize Trp. The major component is consistent with histidine oxidation to 6a-hydroxy-2-oxo-octahydro-pyrollo[2,3-d]imidazole-5-carboxylic acid. Photosensitizer levels measured in the formulation prior to light exposure, are linearly related to the FL-photodegradation observed and can predict degradation in photostability testing.

Expression and characterization of a low molecular weight recombinant human gelatin: development of a substitute for animal-derived gelatin with superior features.

Gelatin is used as a stabilizer in several vaccines. Allergic reactions to gelatins have been reported, including anaphylaxis. These gelatins are derived from animal tissues and thus represent a potential source of contaminants that cause transmissible spongiform encephalopathies. We have developed a low molecular weight human sequence gelatin that can substitute for the animal sourced materials. A cDNA fragment encoding 101 amino acids of the human proalpha1 (I) chain was amplified, cloned into plasmid pPICZalpha, integrated into Pichia pastoris strain X-33, and isolates expressing high levels of recombinant gelatin FG-5001 were identified. Purified FG-5001 was able to stabilize a live attenuated viral vaccine as effectively as porcine gelatin. This prototype recombinant gelatin was homogeneous with respect to molecular weight but consisted of several charge isoforms. These isoforms were separated by cation exchange chromatography and found to result from a combination of truncation of the C-terminal arginine and post-translational phosphorylation. Site-directed mutagenesis was used to identify the primary site of phosphorylation as serine residue 546; serine 543 was phosphorylated at a low level. A new construct was designed encoding an engineered gelatin, FG-5009, with point mutations that eliminated the charge heterogeneity. FG-5009 was not recognized by antigelatin IgE antibodies from children with confirmed gelatin allergies, establishing the low allergenic potential of this gelatin. The homogeneity of FG-5009, the ability to produce large quantities in a reproducible manner, and its low allergenic potential make this a superior substitute for the animal gelatin hydrolysates currently used to stabilize many pharmaceuticals.