STERILISATION EFFECTS ON BIOPHARMACEUTICALS

PREFILLED SYRINGES

Citation: Dierick W, Nakamura K, “Ready-To-Use Prefillable Syringes: Sterilisation Effects on Biopharmaceuticals”. ONdrugDelivery Magazine, Issue 71 (Oct 2016), pp 50-54.

William Dierick and Koji Nakamura report studies comparing the effects of different sterilisation on the extractables and leachables content of biotherapeutic products in prefilled syringes.

Pharmaceutical industry growth is buoyed this year by the expectation that 12 new drugs are forecast to reach blockbuster sales by 2020. Within this market, the biotech sector is a large contributor as indicated by the number of biopharmaceuticals within the top-10 drugs by worldwide sales in 2016. R&D in this space is forecast to continue at a high pace with four biotech products in the top-10 of the biggest launches in 2016.1

Therapeutic proteins are typically administered by injection and by using prefilled syringes (PFS). However, proteins may be sensitive to heat, oxidation and have the propensity to aggregate.2-4 Protein aggregation and the elicitation of anti-drug antibodies (ADAs) may have detrimental effects on drug efficacy, pharmacokinetics and safety. There is evidence that protein aggregation may enhance immunogenicity and this can be an important factor in causing adverse events.5-9 Immunogenicity has been reported with contributing factors related to excipients / formulation and interactions with contact materials of the primary drug container.10-12

Protein-aggregation factors derived from storage in PFS may include silicone oil, usually applied to improve the smooth gliding of the rubber plunger along the barrel, and tungsten oxide, a contaminant derived from the syringe glass manufacturing process.13-16

Figure 1: Comparison of extractables for different methods of sterilisation.

In 2014, these concerns led the US FDA to issue a Guidance for Industry: “Immunogenicity Assessment for Therapeutic Protein Products”. It states that “interactions between therapeutic protein products and the container closure may negatively affect product quality and immunogenicity. These interactions are more likely with prefilled syringes of therapeutic protein products”. In this Guidance, FDA recommends that sponsors should conduct a comprehensive extractables and leachables laboratory assessment using multiple analytical techniques to assess the attributes of the container-closure system that could interact with and degrade protein therapeutic products.17 

With emphasis on the interrelated areas (drug product formulation – container closure system – manufacturing) for therapeutic proteins, the method of sterilisation for prefillable syringes may also become a key factor to mitigate interactions with therapeutic proteins. For sterile ready-to-fill syringes, typical methods of sterilisation include Ethylene Oxide (EtO) gas sterilisation, irradiation (gamma irradiation or e-beam) and steam sterilisation,

Figure 2: Residual EtO profile on polymer PFS.

depending also on the applied materials used in the PFS system.

EXTRACTABLES / RESIDUES FROM DIFFERENT STERILISATION METHODS

New developments have been made in recent years to establish a low-leachable PFS system with a focus on application with therapeutic proteins; particularly PLAJEX™ a cyclo-olefin polymer (COP) PFS with i-coating™ plunger stoppers to eliminate the use of silicone oil as a lubricant of the syringe. These sterile ready-to-use syringes are steam sterilised within the tub/nest presentation.18-21

Terumo evaluated the material of PLAJEX™ prefillable syringes and compared the extractables (and residues) upon using different sterilisation methods. Sterilisation of the materials was conducted respectively with steam sterilisation (121°C for 30 min), EtO (EtO concentration 20%), and irradiation (25 kGy). Extractables were prepared by extractions with water for injection (WFI) at conditions of 121°C for 60 min. The levels of organic compounds in the extractable were determined by liquid chromatography-mass spectrometry (LC-MS) according to methods reported previously.20 Figure 1 shows the graphics of relative abundance obtained by LC-MS. Peaks were detected for irradiated samples whereas no peaks were detected for steam sterilisation and EtO sterilisation. In addition, residual EtO was monitored over time by gas chromatography using headspace sampling. Figure 2 shows the results of residual EtO over time of storage. The potential effect of residual EtO on biopharmaceuticals is not well known and will be subject to our additional research and experiments.

Figure 3: Typical ESR spectra of (A) unsterilised syringe, (B) steam sterilised syringe and (C) syringe irradiated at 25 kGy.

IRRADIATION: RADICAL GENERATION & INFLUENCE ON THERAPEUTIC PROTEINS

Sterilisation by irradiation is a technique commonly applied for polymer-based ready-to-fill syringes. Earlier publications indicated the occurrence of radicals from irradiated polymer-based PFS, affecting the level of protein oxidation as stored in these syringes.23-26

Figure 4: Residual radicals for different methods of sterilisation. Data presented as the mean ±SD (n=3).

Figure 5: Difference in Oxy-Met production during storage of (square) EPO filled into unsterilised syringe, (triangle) steam-sterilised syringe, and (circle) irradiated syringe at 25 kGy, all at 25°C and 65% RH. Data presented as the mean ±SD (n=3).

Figure 6: Transition of radical amount after storage of sterilised syringes by steam sterilisation and irradiation at 25 kGy (stored at 25°C and 65% RH).

Figure 7: Comparison of protein oxidation after filling protein (EPO) into the sterilised syringe and stored at 25°C and 65% RH.

Figure 8. Hypothesis of the protein oxidation mechanism.

CONCLUSION

In consideration of the complexity and challenges associated with the development of therapeutic proteins, different regulatory guidance and directions have been developed over the years, emphasising the importance of assessing the possible interactions between biotherapeutics and the container closure system, as it may have detrimental effects on therapeutic protein quality and immunogencitiy.

PLAJEX™ with i-coating™ plunger stoppers creates a primary drug container that mitigates possible interactions from tungsten, silicone oil and aggregation thereof. Using steam sterilisation as the sterilisation method of ready-to-fill COP syringes may assist in mitigating interactions with the therapeutic protein by reducing the risks of protein oxidation.

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