Development of vaccines and immunotherapeutics has expanded rapidly due to technological advances in the fields of molecular biology and bioprocess engineering, as well as a smoothing of management and material logistics worldwide. Expression platforms and novel cell lines have enabled creation of increasingly complex vaccines. The advancement of vaccine formulation development is also capitalizing on new advances in manufacturing that use model-based methodologies gleaned from physiochemical principles, process analytical tools, and systematic approaches to problem solving. Herein we highlight recent…
October 2013 Supplement
Simpler and More Efficient Viral Vaccine Manufacturing
Human and veterinary vaccines are divided into five main categories: conjugate, toxoid, subunit, inactivated (killed), and live (attenuated) vaccines (1). The vast majority of currently licensed human and veterinary vaccines are inactivated or live (2, 3). They are produced mostly using adherent cells: primary cells such as chicken embryo fibroblasts (CEF), human diploid cells such as MRC-5, or continuous cell lines such as Vero and MDCK (4). The pioneering legacy inherited by vaccine manufacturing development has led to strategies for…
Preparedness Ahead of Pandemic Outbreaks
Lively debate in 2012 concerned the risks and benefits of laboratory studies that created a contagious H5N1 avian pandemic influenza (flu) laboratory-strain virus. One benefit of the public debate is that it reminded governments of the increasingly likely and disastrous possibility of a devastating flu pandemic on the scale of the Spanish influenza outbreak of 1918. Natural evolution of circulating H5N1 viruses could lead to emergence of a deadly and contagious strain (1). Here we outline conventional flu vaccine options…
Inactivated Poliovirus Vaccine Made in Modular Facilities with Single-Use Technology
If current efforts to eradicate polioviruses worldwide are successful, then the oral poliovirus vaccine (OPV) currently used for routine immunization in low- and middle-income countries (LMICs) will be replaced by inactivated poliovirus vaccine (IPV). IPV will become the only option for such countries if they want to continue to vaccinate against polio (1). Because IPV is currently considered to be too expensive for use in LMICs, strategies are being undertaken to make IPV more affordable (2). Some experts estimate that…
From the Editor
With the approaching holiday season and the end of the year — how can that be? — we find ourselves pretty well settled into plans for our 2014 editorial calendar. As a team, we’ve met during the summer to brainstorm and share the results of our research into the subjects of next year’s special reports and supplements. What should we focus on next? What old themes and supplement topics need to be revisited, and what new topics…
Development Strategies for Novel Vaccines for Infectious Diseases
In a vaccine development program, the probability of success at each transition decreases, even though the actual probability of moving from one phase to another can be 50–80% (Figure 1). Many compounds and vaccine candidates are screened out even before they get into preclinical studies. Developers can implement different approaches to reduce product failure risk before a program gets expensive, including Establishing a product development plan (PDP) Identifying and mitigating risk with gap analysis Learning from the mistakes of others…
Development of Protein Capsular Matrix Vaccine Platform Technology
Polysaccharide vaccines account for about 30% of the total >$20-billion/year vaccine market. Despite efficacious vaccines in the field, diseases such as invasive Streptococcus pneumoniae and typhoid fever persist. Development of multivalent polysaccharide conjugate vaccines requires complex chemistries and multiple, expensive good manufacturing practice (GMP) process steps. Matrivax Research and Development Corporation is developing a protein capsular matrix vaccine (PCMV) technology that simplifies synthesis of polysaccharide vaccines with fewer process steps than are required by typical conjugation vaccine processes. Polysaccharide Vaccine…
Container–Closure Integrity
An increasing number of biopharmaceuticals — including vaccines, stem cells, and proteins — require cold storage to maintain efficacy before use. However, the ability to maintain container–closure integrity (CCI) during cold storage is not completely understood. Concerns about CCI failure have been raised for storage and shipment of such products in rubber-stoppered vials under cold conditions (e.g., −80 °C or on dry ice). Commonly used butyl stoppers are believed to lose their elastic properties below their glass transition temperature (Tg),…