| Literature DB >> 25620013 |
Richard Heller1, Loree C Heller1.
Abstract
Plasmid or non-viral gene therapy offers an alternative to classic viral gene delivery that negates the need for a biological vector. In this case, delivery is enhanced by a variety of approaches including lipid or polymer conjugation, particle-mediated delivery, hydrodynamic delivery, ultrasound or electroporation. Electroporation was originally used as a laboratory tool to deliver DNA to bacterial and mammalian cells in culture. Electrode development allowed this technique to be modified for in vivo use. After preclinical therapeutic studies, clinical delivery of cell impermeant chemotherapeutic agents progressed to clinical delivery of plasmid DNA. One huge benefit of this delivery technique is its malleability. The pulse protocol used for plasmid delivery can be fine-tuned to control the levels and duration of subsequent transgene expression. This fine-tuning allows transgene expression to be tailored to each therapeutic application. Effective and appropriate expression induces the desired clinical response that is a critical component for any gene therapy. This chapter focuses on clinical trials using in vivo electroporation or electrotransfer as a plasmid delivery method. The first clinical trial was initiated in 2004, and now more than fifty trials use electric fields for gene delivery. Safety and tolerability has been demonstrated by several groups, and early clinical efficacy results are promising in both cancer therapeutic and infectious disease vaccine applications.Entities:
Keywords: Cancer immunotherapy; Cervical cancer; Clinical trials; DNA vaccines; Electrotransfer; GET; HIV; Hantavirus; Hepatitis B; Hepatitis C; Human papillomavirus; In vivo electroporation; Melanoma; Metastatic disease; Nonviral gene therapy; Prostate cancer; Safety and tolerability; Viral vaccines
Mesh:
Year: 2014 PMID: 25620013 DOI: 10.1016/bs.adgen.2014.10.006
Source DB: PubMed Journal: Adv Genet ISSN: 0065-2660 Impact factor: 1.944