Abstract
Three major directions for the global progress of adeno-associated virus (AAV) vectors for gene therapies (GT) are analyzed: a) engineering vectors to increase transgene expression; b) aligning interests of the health system with costs and challenges for pharmaceutical industry; c) refining patient eligibility criteria, and endpoints definition. Currently employed AAV vectors may cause toxicity and adverse events. Furthermore, studies in animals do not fully predict risks and clinical benefits of AAV-based GT, and animal models reflecting the heterogeneity of certain clinical settings (e.g., congestive heart failure) are poorly available for improving AAV-based GT. Finally, antisense and gene editing approaches will soon complement gene augmentation strategies for the stable solution of unsolved issues of AAV-based GT. While minimizing toxicity, next-generation AAV vectors should decrease the viral load needed to achieve therapeutic efficacy; be functional in a restricted cellular subset; avoid transgene expression in unwanted cells (e.g., hepatocytes), and escape immune oversight in AAV-based GT. The role of stress-induced apoptosis in the loss of transgene expression in GT should be also explored. Aligning interests and obligations of pharmaceutical industry with those of the health system is critical for AAV-based GT success. Costs and challenges for pharmaceutical industry include a) removing impurities from AAV; b) validating tests to measure treatment efficacy, c) promoting training programs to standardize vector genomes delivery, d) collecting long-term follow-up data, and e) maintaining sustainability and cost-effectiveness of AAV-based GT. In rare disorders with small patient numbers (e.g., hemophilia), clearcut outcomes are mandatory as endpoints of unequivocal efficacy data.
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