Coadsorption of a Monoclonal Antibody and Nonionic Surfactant at the SiO<sub>2</sub>/Water Interface

Li, Zongyi; Pan, Fang; Li, Ruiheng; Pambou, Elias; Hu, Xuzhi; Ruane, Sean; Ciumac, Daniela; Li, Peixun; Welbourn, Rebecca J. L.; Webster, John R. P.; Bishop, Steven M.; Narwal, Rojaramani; Walle, Christopher F. van der; Lu, Jian R.

doi:10.1021/acsami.8b16832

Cited by 7 publications

(19 citation statements)

References 39 publications

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“…We show that the behaviour of the mAb and its constituent fragments at the oil/water interface is distinct from that reported previously at air/water and SiO 2 /water interfaces. [20][21][22][23] Our work thus paves the way for future studies directly utilizing PDMS oil to measureing the exact interfacial adsorption of the mAb and its constituent fragments and examining the effects of ionic strength, pH, surfactant co-adsorption, etc., which will advance our understanding of interfacial effects during mAb fill-finish processes and injection device selection. The "straight-through" method is used measure to ( ), the attenuation per unit length of the oil.…”

Section: Summaryconclusionmentioning

confidence: 96%

“…This structural feature is consistent with our previous observed COE-3 conformation adsorbed at the air/water 21 and hydrophilic silica/water interfaces. 22 In their QCM-D study of how several mAbs adsorbed to interfaces coated with hydrophobic silanes, Wiseman and Frank also concluded that monolayers of globular mAbs had been formed at the surface. 27…”

Section: Reflectivity Data Fitted To a One-layer Modelmentioning

confidence: 99%

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Interfacial Adsorption of a Monoclonal Antibody and Its Fab and Fc Fragments at the Oil/Water Interface

Ruane

Campana

et al. 2019

Langmuir

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The physical stability of a monoclonal antibody (mAb) solution for injection in a pre-filled syringe may in part depend on its behaviour at the silicone oil/water interface. Here, the adsorption of a mAb (termed COE-3) and its fragment antigen-binding (Fab) and crystallisable (Fc) at the oil/water interface were measured using neutron reflection. A 1.4±0.1 µm hexadecane oil film was formed on a sapphire block by a Spin-Freeze-Thaw process in order to retain its integrity upon contact with the protein solutions. Measurements revealed that adsorbed COE-3, its Fab and Fc retained their globular structure, forming layers that did not penetrate substantially into the oil phase. COE-3 and Fc were found to adsorb flat-on to the interface, with a denser 45 and 42 Å inner layer, respectively, in contact with the oil and a more diffuse 17-21 Å outer layer caused by fragments adsorbing in a tilted manner. In contrast, Fab fragments formed a uniform 60 Å monolayer. Monolayers were formed under all conditions studied (10-200 ppm, using three isotopic contrasts), though changes in packing density across the COE-3 and Fc layers were observed. COE-3 had a higher affinity to the interface than either of its constituent fragments, while Fab had a lower interfacial affinity consistent with its higher net surface charge. This study extends the application of high resolution neutron reflection measurements to the study of protein adsorption at the oil/water interface using an experimental set-up mimicking the protein drug product in a siliconized prefilled syringe.

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Section: Summaryconclusionmentioning

confidence: 96%

Section: Reflectivity Data Fitted To a One-layer Modelmentioning

confidence: 99%

Interfacial Adsorption of a Monoclonal Antibody and Its Fab and Fc Fragments at the Oil/Water Interface

Ruane

Campana

et al. 2019

Langmuir

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“…A study by Kim et al [77] showed that polysorbates were able to inhibit protein adsorption but did not result in a protein/surfactant complex with an overall lower surface activity. To add to this, Li et al [78] have recently shown that PS 80 and C 12 E 5 could not prevent COE-3 adsorption at the SiO 2 /water interface. When a polysorbate 80 analogue with 7 ethoxylates (PS80-7EO) was used, it co-adsorbed but did not affect the equilibrated amount of adsorption from COE-3.…”

Section: The Sio 2 /Water Interfacementioning

confidence: 99%

Recent Advances in Studying Interfacial Adsorption of Bioengineered Monoclonal Antibodies

Hollowell

et al. 2020

Molecules

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Monoclonal antibodies (mAbs) are an important class of biotherapeutics; as of 2020, dozens are commercialized medicines, over a hundred are in clinical trials, and many more are in preclinical developmental stages. Therapeutic mAbs are sequence modified from the wild type IgG isoforms to varying extents and can have different intrinsic structural stability. For chronic treatments in particular, high concentration (≥ 100 mg/mL) aqueous formulations are often preferred for at-home administration with a syringe-based device. MAbs, like any globular protein, are amphiphilic and readily adsorb to interfaces, potentially causing structural deformation and even unfolding. Desorption of structurally perturbed mAbs is often hypothesized to promote aggregation, potentially leading to the formation of subvisible particles and visible precipitates. Since mAbs are exposed to numerous interfaces during biomanufacturing, storage and administration, many studies have examined mAb adsorption to different interfaces under various mitigation strategies. This review examines recent published literature focusing on adsorption of bioengineered mAbs under well-defined solution and surface conditions. The focus of this review is on understanding adsorption features driven by distinct antibody domains and on recent advances in establishing model interfaces suitable for high resolution surface measurements. Our summary highlights the need to further understand the relationship between mAb interfacial adsorption and desorption, solution aggregation, and product instability during fill-finish, transport, storage and administration.

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“…Protein adsorption onto solid substrates is a widespread phenomenon, and its prevention is critical for proper functioning of medical devices and implants, as well as in bioseparation and other applications involving surfaces prone to contamination. − The adsorption of proteins in these cases is largely of a nonspecific nature, and there is little control over the structure and composition of the adsorbed protein layer. When proteins from blood are adsorbed onto the surfaces of medical implants, the interfacial processes could undermine device integration at an early stage, trigger adverse cellular responses, and compromise the device’s performance and fate.…”

Section: Introductionmentioning

confidence: 99%

“…Specular NR is capable of quantitative determination of the thickness and uniformity of an interfacial layer with subnanometer sensitivity along the surface normal direction. ,,,− It effectively determines how the volume fraction (ϕ) of the layer varies with the distance perpendicular to the interface. The technique has been widely used in determining the interfacial layer structure of a variety of soft matters such as surfactants, − peptides, ,,,,, proteins, − antibodies, ,− DNAs, , polymers, and lipids. , As an example system, we employed a set of peptoid peptidomimetic polymers (PMPs) that we have previously demonstrated to prevent protein adsorption and cell attachment above certain chain length-dependent critical grafted chain densities. ,, PMPs form an excellent model brush system because of their exact chain lengths controlled by solid phase synthesis. , …”

Section: Introductionmentioning

confidence: 99%

Interfacial Assembly Inspired by Marine Mussels and Antifouling Effects of Polypeptoids: A Neutron Reflection Study

et al. 2020

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Polypeptoid-coated surfaces and many surface-grafted hydrophilic polymer brushes have been proven efficient in antifouling-the prevention of nonspecific biomolecular adsorption and cell attachment. Protein adsorption, in particular, is known to mediate subsequent cell-surface interactions. However, the detailed antifouling mechanism of polypeptoid and other polymer brush coatings at the molecular level is not well understood. Moreover, most adsorption studies focus only on measuring a single adsorbed mass value, and few techniques are capable of characterizing the hydrated in situ layer structure of either the antifouling coating or adsorbed proteins. In this study, interfacial assembly of polypeptoid brushes with different chain lengths has been investigated in situ using neutron reflection (NR). Consistent with past simulation results, NR revealed a common two-step structure for grafted polypeptoids consisting of a dense inner region that included a mussel adhesive-inspired oligopeptide for grafting polypeptoid chains and a highly hydrated upper region with very low polymer density (molecular brush). Protein adsorption was studied with human serum albumin (HSA) and fibrinogen (FIB), two common serum proteins of different sizes but similar isoelectric points (IEPs). In contrast to controls, we observed higher resistance by grafted polypeptoid against adsorption of the larger FIB, especially for longer chain lengths. Changing the pH to close to the IEPs of the proteins, which generally promotes adsorption, also did not significantly affect the antifouling effect against FIB, which was corroborated by atomic force microscopy imaging. Moreover, NR enabled characterization of the in situ hydrated layer structures of the polypeptoids together with proteins adsorbed under selected conditions. While adsorption on bare SiO 2 controls resulted in surface-induced protein denaturation, this was not observed on polypeptoids. Our current results therefore highlight the detailed in situ view that NR may provide for characterizing protein adsorption on polymer brushes as well as the excellent antifouling behavior of polypeptoids.

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Coadsorption of a Monoclonal Antibody and Nonionic Surfactant at the SiO₂/Water Interface

Cited by 7 publications

References 39 publications

Interfacial Adsorption of a Monoclonal Antibody and Its Fab and Fc Fragments at the Oil/Water Interface

Interfacial Adsorption of a Monoclonal Antibody and Its Fab and Fc Fragments at the Oil/Water Interface

Recent Advances in Studying Interfacial Adsorption of Bioengineered Monoclonal Antibodies

Interfacial Assembly Inspired by Marine Mussels and Antifouling Effects of Polypeptoids: A Neutron Reflection Study

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Coadsorption of a Monoclonal Antibody and Nonionic Surfactant at the SiO2/Water Interface

Cited by 7 publications

References 39 publications

Interfacial Adsorption of a Monoclonal Antibody and Its Fab and Fc Fragments at the Oil/Water Interface

Interfacial Adsorption of a Monoclonal Antibody and Its Fab and Fc Fragments at the Oil/Water Interface

Recent Advances in Studying Interfacial Adsorption of Bioengineered Monoclonal Antibodies

Interfacial Assembly Inspired by Marine Mussels and Antifouling Effects of Polypeptoids: A Neutron Reflection Study

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Coadsorption of a Monoclonal Antibody and Nonionic Surfactant at the SiO₂/Water Interface