Novel protein immobilization approaches for the development of vaccine candidates and enzymatic reactors

Protein immobilization on solid supports offers a wide range of opportunities in the biotech industry. Its many possible applications in diverse fields cover from enzyme immobilization promoting an enhancement in the physicochemical properties, to vaccine candidate generation, reducing the associated production costs and improving the immunogenic performance of the vaccine candidate. The immobilization process implicates profound science in both substrate surface and proteins. Proteins are composed of amino acids polymerized jointly through the formation of peptide bonds. One or more polypeptide chains fold into a 3- dimensional (3-D) bioactive protein, with many exposed functional groups such as carboxyl, amine, hydroxyl, and sulfhydryl. Regarding the immobilization strategy, the conformation of the immobilized protein needs to be seriously considered. In the enzyme field, the active site is usually a groove or pocket where the target or substrate molecules bind and experience a chemical reaction. In order to function properly, this active site needs to be in specific and appropriate conformation and accessible to the target. The present study explores two fundamentally different methods for protein immobilization: the IC-Tagging methodology using a modified viral protein, and 3D printing thought the use of Stereolithography (SLA). We investigate the feasibility of these strategies and its efficiency in generating properly folded immobilized proteins for different applications in the field of biocatalysts and cancer immunotherapy

Advancing rare disease treatment: EMA’s decade-long insights into engineered adoptive cell therapy for rare cancers and orphan designation

Abstract Adoptive cell therapy (ACT), particularly chimeric antigen receptor (CAR)-T cell therapy, has emerged as a promising approach for targeting and treating rare oncological conditions. The orphan medicinal product designation by the European Union (EU) plays a crucial role in promoting development of medicines for rare conditions according to the EU Orphan Regulation. This regulatory landscape analysis examines the evolution, regulatory challenges, and clinical outcomes of genetically engineered ACT, with a focus on CAR-T cell therapies, based on the European Medicines Agency’s Committee for Orphan Medicinal Products review of applications evaluated for orphan designation and maintenance of the status over a 10-year period. In total, 30 of 36 applications were granted an orphan status, and 14 subsequently applied for maintenance of the status at time of marketing authorisation or extension of indication. Most of the products were autologous cell therapies using a lentiviral vector and were developed for the treatment of rare haematological B-cell malignancies. The findings revealed that 80% (29/36) of the submissions for orphan designation were supported by preliminary clinical data showing a potential efficacy of the candidate products and an added clinical benefit over currently authorised medicines for the proposed orphan condition. Notably, in 89% (32/36) of the cases significant benefit of the new products was accepted based on a clinically relevant advantage over existing therapies. Twelve of fourteen submissions reviewed for maintenance of the status at time of marketing authorisation or extension of indication demonstrated significant benefit of the products over existing satisfactory methods of treatment within the approved therapeutic indications, but one of the applications was withdrawn during the regulatory evaluation. This article summarises the key findings related to the use of engineered ACT, primarily CAR-T cell therapies, in targeting and treating rare cancers in the EU. It emphasises the importance of use of clinical data in supporting medical plausibility and significant benefit at the stage of orphan designation and highlights the high success rate for these products in obtaining initial orphan designations and subsequent maintaining the status at the time of marketing authorisation or extension of indication

The European landscape for gene therapies in orphan diseases: 6-year experience with the EMA Committee for Orphan Medicinal Products

In 2000, the European Union (EU) introduced the orphan pharmaceutical legislation to incentivize the development of medicinal products for rare diseases. The Committee for Orphan Medicinal Products (COMP), the European Medicines Agency committee responsible for evaluation of applications for orphan designation (OD), received an increasing flow of applications in the field of gene therapies over the last years. Here, the COMP has conducted a descriptive analysis of applications regarding gene therapies in non-oncological rare diseases, with respect to (a) targeted conditions and their rarity, (b) characteristics of the gene therapy products proposed for OD, with a focus on the type of vector used, and (c) regulatory aspects pertaining to the type of sponsor and development, by examining the use of available frameworks offered in the EU such as protocol assistance and PRIME. It was noted that gene therapies are being developed by sponsors from different backgrounds. Most conditions being targeted are monogenic, the most common being lysosomal disorders, and with a very low prevalence. Generally, adeno-associated viral vectors were being used to deliver the transgene. Finally, sponsors are not frequently using the incentives that may support the development and the reasons for this are unclear