Oxidation of the protein therapeutic can also present challenges for the biomanufacturer where it can lead to a range of functional issues such as altered binding activities, increased susceptibility to aggregation and proteolysis, increased or decreased uptake by cells, and altered immunogenicity. The rate of oxidation can be affected by a number of factors (particularly during storage) including oxygen (head space), light, the physical state of the product, and temperature.
Insulin-like growth factor-I (IGF-I), an important anabolic growth factor, has been shown to be susceptible to oxidation. To test the functionality of rAlbumin as an antioxidant, pharmaceutically relevant conditions in protein oxidation were modeled using trace amounts of hydrogen peroxide (H2O2). rAlbumin or L-methionine were dissolved in a solution of PBS buffer. The IGF-I protein was then added to all samples followed by H2O2 to a final concentration of 0.0005%.
The reaction was terminated and degree of oxidation analyzed. Oxidation of IGF-I was shown to be significantly reduced by the presence of increasing concentrations of rAlbumin and the highest concentration reduced oxidation of IGF-I by 93%.
The study also assessed the ability of rAlbumin to act as an antioxidant following exposure to hydrogen peroxide when compared to the commonly used antioxidant L-methionine (Figure 2). The oxidative protection of IGF-I by rAlbumin was achieved at molar concentrations ~13-fold less than that of L-methionine. The antioxidant function of HSA is primarily due to the single free-thiol at position Cys 34, where HSA-SH acts as a potential scavenger for reactive oxygen and nitrogen species.
The loss of drug product due to non-specific adsorption to surfaces can decrease the concentration in solution, significantly altering the efficacy of the drug. Structural change, denaturation, and inactivation are also results of nonspecific adsorption and present a particular problem for products administered at low concentrations. Many surfaces that a drug product may come in contact with during manufacturing processes such as delivery pumps, silicone tubing, and glass and plastic containers, can lead to product losses.
HSA has been utilized as a blocking agent to prevent therapeutic proteins binding to various surfaces. Though the mechanism is not well understood, albumin is thought to bind to charged surfaces through opposite charged functional groups on the molecule.
Hydrophobic interactions also occur but at lower strength and are more easily reversible. Transforming growth factor-β3 (TGF-β3), an active pharmaceutical ingredient, is a hydrophobic protein with a propensity to adsorb to container surfaces. The percentage loss of TGF-β3 due to nonspecific binding to polypropylene or glass vial surfaces in the absence and presence of rAlbumin was also examined.
TGF-β3 was added to a polypropylene or glass container containing citrate buffer (pH 3.6). Samples were analyzed and percentage recovery of TGF-β3 was calculated against the TGF-β3 reference standard. rAlbumin was then assessed for its ability to prevent the loss of TGF-β3 to the container surface.
The study demonstrated that rAlbumin significantly reduced protein loss due to nonspecific binding of TGF-β3 to glass and plastic. In the absence of rAlbumin, nonspecific binding increased progressively at concentrations less than 60 µg/mL, and the recovery of the protein was significantly reduced at lower concentrations.
However, in the presence of rAlbumin the nonspecific binding of TGF-b3 to vessel surfaces was minimal with >95% recovery achieved using just 0.05 mg/mL of rAlbumin.