Impact of tubing material on stability and filling accuracy of biologic drug product.

This article is presenting completely new observations linked to Polysorbate 80 (PS80) oxidation in biologics drug product. Indeed, we observed that, in the drug product exposed to long contact time (∼ 1 h) in platinum-cured silicon tubing during the filling, the oxidation of PS80 is dramatically accelerated compared to short contact time. The phenomenon was observed in presence of iron traces (20 ppb), but not in absence of iron (< 2 ppb) or in presence of a chelator like EDTA. Electron Paramagnetic Resonance (EPR) measurements demonstrated the presence of radicals formed during the oxidation. It was deduced that platinum-cured silicon tubing is leaching some radical initiators, most probably peroxides decomposed by the iron. Alternative filling sets made of ThermoPlastic Elastomer (TPE) were investigated, both for the impact on PS80 stability and the filling performance using a peristaltic pump. The results showed that these filling sets were indeed not causing accelerated PS80 degradation but the process was not robust enough; these filling sets being too rigid for the constraints of the peristaltic pump rollers. These results show that there is no practical tubing alternative to platinum silicone cured tubing. To avoid the impact on PS80 oxidation the potential remediations presented in the article are to avoid any trace of iron or to add a chelating agent, or to discard the vials having experimented a filling stop (> 5 min).

Optimal self-assembly of lipid nanoparticles (LNP) in a ring micromixer.

Lipid nanoparticles (LNPs) for RNA and DNA delivery have attracted considerable attention for their ability to treat a broad range of diseases and to vectorize mRNA for COVID vaccines. LNPs are produced by mixing biomolecules and lipids, which self-assemble to form the desired structure. In this domain, microfluidics shows clear advantages: high mixing quality, low-stress conditions, and fast preparation. Studies of LNPs produced in micromixers have revealed, in certain ranges of flow rates, a degradation in performance in terms of size, monodispersity and encapsulation efficiency. In this study, we focus on the ring micromixer, which is well adapted to high throughput. We reveal three regimes, side-by-side, transitional and highly mixed, that control the mixing performance of the device. Furthermore, using cryo-TEM and biochemical analysis, we show that the mixing performances are strongly correlated to the characteristics of the LNPs we produce. We emphasize the importance of the flow-rate ratio and propose a physical criterion based on the onset of temporal instabilities for producing LNPs with optimal characteristics in terms of geometry, monodispersity and encapsulation yield. These criteria are generally applicable.

Mixing of Monoclonal Antibody Formulated Drug Substance Solutions in Square Disposable Vessels.

Fill & finish manufacturing processes of biologics drug product involve multiple unit operations. In particular they often include a mixing step to reduce non-uniformities in fluids by eliminating gradients of concentration and pH may occur during freezing. This step should be conducted carefully to avoid any degradation of the protein under mechanical stress. This study was aimed at characterizing disposable vessels of square cross-section such as Levmixer® from Sartorius Stedim in terms of fluid dynamics and mixing in turbulent regime. The investigation included two tree large vessels (50, 200 & 650-l) and one 4-l vessel designed in house. For that purpose, the impact of stirrer speed, filling volume and duration of mixing on product quality attributes were studied, using a surrogate. Moreover, a scale-up rule, based on first principle, was established and allows prediction of the mixing time as a function of stirring speed and filling volume. A lab-scale test, using drug product, was performed at the same stress intensity but for a much longer duration than the commercial operation and did not reveal any trend to aggregation. Finally, based on the correlation, lab scale stress test and a single verification test at large scale, a design space within which the product can be processed without altering product quality was proposed.

Mechanistic understanding of metal-catalyzed oxidation of polysorbate 80 and monoclonal antibody in biotherapeutic formulations.

Surfactants are commonly used in biotherapeutic formulations to prevent the formation of aggregates and protect proteins from denaturation. Among them polysorbates are the most widely used. However, they are known to be prone to degradation, mainly via enzymatic hydrolysis and oxidation. In this study, the impact of different conditions and factors on the oxidation of polysorbate 80 (PS80) and of a monoclonal antibody (mAb) was evaluated. In particular, the role of different formulation components (e.g., mAb concentration, pH, buffer, surfactant grade, chelators) was investigated in the presence of iron as transition metal contaminant. The results of our studies demonstrated that PS80 oxidation was accelerated even in the presence of iron levels as low as 20 ppb. In addition, the results showed that the oxidation of a specific solvent-exposed mAb methionine increased with PS80 oxidation, in particular under accelerated stress conditions and that the oxidation phenomenon was hindered in absence of iron or after addition of EDTA. Our results showed that PS80 "all oleate" (PS80-AO) was more sensitive to oxidative degradation than PS80 "multi-compendial" (PS80-MC). Contrary to acetate and citrate buffers, the results showed that the kinetics of PS80 oxidation was pH-dependent in presence of histidine buffer. It was also demonstrated that, when increasing its concentration, the mAb exhibited a protective effect against metal catalyzed PS80 and methionine oxidation. Our systematic studies on the role of the formulation components and potential contaminants (i.e., iron) demonstrated the complexity of the oxidative mechanism and the importance of different competitive systems, including pro-oxidant factors (e.g., iron, pH, PS80 quality) and antioxidant factors (e.g., protein concentration, EDTA, citrate) that may occur in biologic formulations containing PS80.

NLS bioconjugates for targeting therapeutic genes to the nucleus.

One of the major steps limiting non-viral gene transfer efficiency is the entry of plasmid DNA from the cytoplasm into the nucleus of transfected cells. Trafficking of nuclear proteins from the cytoplasm into the nucleus through nuclear pore complexes is mediated by the presence of nuclear localization sequences (NLS) on proteins. Viral DNA and RNA also require interaction with cellular machinery for efficient nuclear import. In this article, we review the various strategies used to provide plasmid DNA with nuclear localization sequences, and discuss the possibility of developing efficient gene delivery systems based on these strategies.

Folate-targeted gene transfer in vivo.

Nonviral systemic delivery is one of the most attractive approaches for cancer gene therapy. To achieve this goal, various laboratories have developed cationic liposomes. However, when injected intravenously, cationic lipid-DNA complexes accumulate mostly into and transfect lung tissue. Here, we describe a method by which these complexes can be targeted to tumors using folic acid. Adding polyethylene glycol (PEG)-lipids to the complexes dramatically reduced both lung accumulation and gene transfer to lungs and tumors after intravenous administration. The presence of folic acid at the distal end of the PEG-lipid did not modify tumor accumulation of the complexes. However, with folate-targeted complexes, gene transfer activity was restored in tumors while the activity in lungs was reduced by 50- to 100-fold compared with nontargeted lipid-DNA complexes. This approach provides a first in vivo proof of concept to achieve targeted tumor gene delivery.