Attribute Analytics Performance Metrics from the MAM Consortium Interlaboratory Study.

The multi-attribute method (MAM) was conceived as a single assay to potentially replace multiple single-attribute assays that have long been used in process development and quality control (QC) for protein therapeutics. MAM is rooted in traditional peptide mapping methods; it leverages mass spectrometry (MS) detection for confident identification and quantitation of many types of protein attributes that may be targeted for monitoring. While MAM has been widely explored across the industry, it has yet to gain a strong foothold within QC laboratories as a replacement method for established orthogonal platforms. Members of the MAM consortium recently undertook an interlaboratory study to evaluate the industry-wide status of MAM. Here we present the results of this study as they pertain to the targeted attribute analytics component of MAM, including investigation into the sources of variability between laboratories and comparison of MAM data to orthogonal methods. These results are made available with an eye toward aiding the community in further optimizing the method to enable its more frequent use in the QC environment.

New Peak Detection Performance Metrics from the MAM Consortium Interlaboratory Study.

The Multi-Attribute Method (MAM) Consortium was initially formed as a venue to harmonize best practices, share experiences, and generate innovative methodologies to facilitate widespread integration of the MAM platform, which is an emerging ultra-high-performance liquid chromatography-mass spectrometry application. Successful implementation of MAM as a purity-indicating assay requires new peak detection (NPD) of potential process- and/or product-related impurities. The NPD interlaboratory study described herein was carried out by the MAM Consortium to report on the industry-wide performance of NPD using predigested samples of the NISTmAb Reference Material 8671. Results from 28 participating laboratories show that the NPD parameters being utilized across the industry are representative of high-resolution MS performance capabilities. Certain elements of NPD, including common sources of variability in the number of new peaks detected, that are critical to the performance of the purity function of MAM were identified in this study and are reported here as a means to further refine the methodology and accelerate adoption into manufacturer-specific protein therapeutic product life cycles.

Thyroid stimulating hormone increases iodine uptake by thyroid cancer cells during BRAF silencing.

BACKGROUND: The BRAF(V600E) mutation is present in 62% of radioactive iodine-resistant thyroid tumors and is associated with downregulation of the sodium-iodide symporter (NIS) and thyroid stimulating hormone receptor (TSHr). We sought to evaluate the combined effect of BRAF inhibition and TSH supplementation on (131)I uptake of BRAF(V600E)-mutant human thyroid cancer cells. MATERIALS AND METHODS: WRO cells (a BRAF(V600E)-mutant follicular-derived papillary thyroid carcinoma cell line) were transfected with small interfering RNA targeting BRAF for 72 h in a physiological TSH environment. NIS and TSHr expression were then evaluated at three levels: gene expression, protein levels, and (131)I uptake. These three main outcomes were then reassessed in TSH-depleted media and media supplemented with supratherapeutic concentrations of TSH. RESULTS: NIS gene expression increased 5.5-fold 36 h after transfection (P = 0.01), and TSHr gene expression increased 2.8-fold at 24 h (P = 0.02). NIS and TSHr protein levels were similarly increased 48 and 24 h after transfection, respectively. Seventy-two hours after BRAF inhibition, (131)I uptake was unchanged in TSH-depleted media, increased by 7.5-fold (P < 0.01) in physiological TSH media, and increased by 9.1-fold (P < 0.01) in supratherapeutic TSH media. CONCLUSIONS: The combined strategy of BRAF inhibition and TSH supplementation results in greater (131)I uptake than when either technique is used alone. This represents a simple and feasible approach that may improve outcomes in patients with radioactive iodine-resistant thyroid carcinomas for which current treatment algorithms are ineffective.

Self-assembled nanoplatform for targeted delivery of chemotherapy agents via affinity-regulated molecular interactions.

Site-specific delivery of drugs while minimizing unwanted distribution has been one of the pursued goals in cancer therapy. In this endeavor, we have developed targeted polymeric nanoparticles called amphiphilic urethane acrylate nonionomer (UAN) for encapsulation of diverse water-insoluble drugs and diagnostic agents, as well as for simple and reproducible surface conjugation of targeting ligands. Using monoclonal antibodies or lymphocyte function-associated antigen-1 (LFA-1) I domain engineered for varying affinities to intercellular adhesion molecule (ICAM)-1, we were able to deliver UAN nanoparticles to human cancer cells with the efficiency dependent on the strength of the molecular interactions and the degree of ICAM-1 expression on cell surface. Compared to non-specific uptake of free drugs, targeted delivery of UAN nanoparticles carrying equal amount of drugs produced more potent cytotoxicity. Notably, without the targeting ligands attached, UAN nanoparticles were largely precluded from non-specific uptake by the cells, resulting in much lower toxicity. The versatility of our UAN nanoparticles in both payload encapsulation and presentation of targeting ligands may facilitate developing a robust platform for evaluating various combinations of cancer drugs and molecular interactions toward developing effective cancer therapy formulations.