A Phase I, Randomized, Controlled Dosage-Escalation Study of the Safety and Reactogenicity of the EP1300 Polyepitope DNA Vaccine Against Plasmodium Falciparum Malaria Administered Via Electroporation to Healthy Adults

Malaria, a disease responsible for over one million deaths per year, is caused by a germ spread by mosquito bites. The purpose of this study is to evaluate a vaccine designed for the prevention of malaria caused by the parasite, Plasmodium falciparum, and to evaluate the device used to give the vaccine. This study will provide information on how safe, effective, and tolerable the vaccine is in healthy adults. The participants will be assigned, by chance, to receive 3 doses/shots of the vaccine or a placebo (substance that contains no medication) by injection in the upper arm. Study participants will include 39 healthy adults aged 18-40 years who have not been exposed to malaria and who will enroll at the Emory Vaccine and Treatment Evaluation Unit in Atlanta, Georgia. Study procedures include physical exams and several blood samples. Participants will be involved in the study for approximately seven and one half months.

Start Date01 Aug 2010

Sponsor / Collaborator

National Institute of Allergy & Infectious Diseases

100 Clinical Results associated with Malaria DNA vaccine(Pharmexa-Epimmune, Inc.)

100 Translational Medicine associated with Malaria DNA vaccine(Pharmexa-Epimmune, Inc.)

100 Patents (Medical) associated with Malaria DNA vaccine(Pharmexa-Epimmune, Inc.)

Literatures (Medical) associated with Malaria DNA vaccine(Pharmexa-Epimmune, Inc.)

01 Nov 2016·VaccineQ3 · MEDICINE

A phase 1, randomized, controlled dose-escalation study of EP-1300 polyepitope DNA vaccine against Plasmodium falciparum malaria administered via electroporation

Q3 · MEDICINE

Article

Author: Spearman, Paul ; Mulligan, Mark ; Shane, Andi L ; Singh, Karnail ; Hartwell, Brooke ; Hannaman, Drew ; Anderson, Evan J ; Stephens, Kathy ; Watson, Nora L ; Gibson, Theda

Plasmodium falciparum malaria is one of the leading infectious causes of childhood mortality in Africa. EP-1300 is a polyepitope plasmid DNA vaccine expressing 38 cytotoxic T cell epitopes and 16 helper T cell epitopes derived from P. falciparum antigens expressed predominantly in the liver phase of the parasite's life cycle. We performed a phase 1 randomized, placebo-controlled, dose escalation clinical trial of the EP-1300 DNA vaccine administered via electroporation using the TriGrid Delivery System device (Ichor Medical Systems). Although the delivery of the EP-1300 DNA vaccine via electroporation was safe, tolerability was less than that usually observed with standard needle and syringe intramuscular administration. This was primarily due to acute local discomfort at the administration site during electroporation. Despite the use of electroporation, the vaccine was poorly immunogenic. The reasons for the poor immunogenicity of this polyepitope DNA vaccine remain uncertain.CLINICAL TRIALS REGISTRATIONClinicalTrials.gov NCT01169077.

01 Jan 2016·YAKUGAKU ZASSHIQ4 · MEDICINE

Development of a Multi-functional Nano-device for Safe and Effective Gene Delivery to Target Organs

Q4 · MEDICINE

Review

Author: Kodama, Yukinobu

Nucleic acids are expected as novel effective medicines, although they require a drug delivery system (DDS). Complexes of nucleic acids with cationic liposomes and cationic polymers have been mainly used as DDS for clinical use. However, most cationic complexes have disadvantages such as strong cytotoxicity and low biocompatibility. We previously found that a plasmid DNA (pDNA) complex coated with biodegradable γ-polyglutamic acid (γ-PGA) provided adequate gene expression without cytotoxicity. Based on these results, we developed a new DDS (multi-functional Nano-device) of pDNA using biodegradable polyamino acids. A typical cationic polyamino acid, poly-L-lysine (PLL), was complexed with pDNA. The binary complexes, however, showed low gene expression and high cytotoxicity. Gene expression was enhanced by addition of poly-L-histidine (PLH) to the binary complexes. PLH can increase endosome escape of the complexes by inducing pH-buffering effects. The quaternary complexes (pDNA-PLL-PLH-γ-PGA complexes) exhibited high gene expression and low cytotoxicity. Furthermore, we used dendrigraft poly-L-lysine (DGL) instead of PLL and PLH to enhance gene expression. DGL had sterically congested cations and was biodegradable. The ternary complexes (pDNA-DGL-γ-PGA complexes) exhibited markedly high gene expression and low cytotoxicity. The pDNA-DGL-γ-PGA complexes also had high gene expression in the marginal zone (rich dendritic cells) of the spleen after intravenous injection into mice. These results indicate that pDNA-DGL-γ-PGA complexes may be useful as vaccine vectors. Therefore we prepared a novel malaria DNA vaccine using Plasmodium yoelii GPI8p-transamidase-related protein pDNA (PyTAM). The PyTAM-DGL-γ-PGA complexes markedly improved survival time of model mice infected with malaria.

01 Jun 2015·Parasitology ResearchQ3 · MEDICINE

Malaria DNA vaccine gp96NTD-CSP elicits both CSP-specific antibody and CD8+ T cell response

Q3 · MEDICINE

Article

Author: TaoLi Zhou ; Wenyue Xu ; Yan Ding ; Zhangping Tan ; Hong Zheng

It is ideal for the pre-erythrocytic stage subunit vaccine to induce both CSP-specific antibody and CD8(+) T cell response. Here, we designed a novel malaria DNA vaccine gp96NTD-CSP, which was constructed by fusing the full-length of CSP with the N-terminal domain of gp96 that deleted the endoplasmic reticulum-localized motif KDEL, and investigated its protective efficacy. We found that the fusion protein gp96NTD-CSP was mainly distributed on the surface of eukaryotic cells after transfection and could be sensed as a "danger signal" by the host immune system. Interestingly, both liver parasite burden and parasitemia in mice immunized with gp96NTD-CSP were significantly lower than those in the mice immunized either with gp96NTD, CSP, or gp96NTD-SYVPSAEQI, which was constructed by fusing the CSP-specific CD8(+) T cell epitope with the N-terminal domain of gp96 deleted with KDEL. Consistently, both the level of CSP-specific antibody and the frequency of IFN-γ secreted-CSP-specific CD8(+) T cells were much higher in mice immunized with gp96NTD-CSP than those in the mice immunized either with gp96NTD, CSP, or gp96NTD-SYVPSAEQI. Our results suggest that the malaria DNA vaccine gp96NTD-CSP could induce both humoral and cellular immune responses, which is attributed to the adjuvant effect of gp96NTD and full-length CSP.

100 Deals associated with Malaria DNA vaccine(Pharmexa-Epimmune, Inc.)

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Indication	Highest Phase	Country/Location	Organization	Date
Malaria	Phase 1	US	Pharmexa-Epimmune, Inc.	-
Malaria	Phase 1	US	KAEL-GemVax Co., Ltd.	-
Malaria	Phase 1	US	National Institutes of Health	-

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