High Efficacy Vaccine and Microbicide Combination For Use Against HIV

Human immunodeficiency virus (HIV) remains a major global health challenge despite the advancement made in development of effective antiretrovirals (ARVs). ARVs are effective at limiting replication and spread of the virus, and progression to acquired immuno-deficiency syndrome (AIDS). However, ARVs often lead to emergence of drug-resistant virus strains insensitive to treatment and with toxic effects following long-term usage.

Vaccines for HIV

The development of an effective HIV vaccine has been an ongoing area of research. The high variability in HIV-1 virus strains has represented a major challenge in successful development.  Ideally, an effective candidate vaccine would provide protection against the majority of clades of HIV.  Two major hurdles to overcome are immunodominance and sequence diversity.  This vaccine utilizes a strategy for overcoming these two issues by identifying the conserved regions of the virus and exploiting them for use in a targeted therapy. 

A Dendritic Cell Vaccine to Immunize Cancer Patients Against Mutated Neoantigens Expressed by the Autologous Cancer

Vaccines against non-viral cancers target mainly differentiation antigens, cancer testis antigens, and overexpressed antigens.  One common feature to these antigens is their presence in central immunological tolerance. Using these vaccines, T cells underwent depletion of high avidity clones directed against such antigens. This depletion can cause the loss of T cells bearing high affinity T cell receptors (TCRs) for their cognate antigens which have superior cytotoxic capacity, longer persistence in the tumor microenvironment, and decreased susceptibility to immune suppression.

Multi-epitope Vaccines against TARP (ME-TARP) for Treating Prostate and Breast Cancer

The development of more targeted means of treating cancer is vital. One option for a targeted treatment is the creation of a vaccine that induces an immune response only against cancer cells. In this sense, vaccination involves the introduction of a peptide into a patient that causes the formation of antibodies or T cells that recognize the peptide. If the peptide is from a protein found selectively on/in cancer cells, those antibodies or T cells can trigger the death of those cancer cells without harming non-cancer cells. This can result in fewer side effects for the patient.

Cancer Vaccines against POTE for Treating Solid Tumors

POTE is a novel tumor antigen expressed in a variety of cancers including breast, prostate, colon, lung, ovary, and pancreas cancers.  POTE has limited expression in normal tissues and therefore a specific target for cancer treatments, including immunotherapy.  The researchers seek statements of capability or interest from parties interested in collaborative research to further develop, evaluate, or commercialize immunogenic peptides. 

Conserved Elements Vaccine for HIV

The development of an effective HIV vaccine has been an ongoing area of research. High variability in HIV-1 virus strains, however,  represents a major challenge.  Ideally, an effective candidate vaccine would provide protection against the majority of clades of HIV.  Two major hurdles to overcome are immunodominance and sequence diversity. Researchers at the National Cancer Institute (NCI) have developed a vaccine that overcomes these major hurdles by utilizing a strategy that identifies conserved regions of the virus and exploits them for use in a targeted therapy.

Immunogens for Use in a High Efficacy HIV Vaccine

Human immunodeficiency virus (HIV) infections remain a pandemic, most prevalent in Africa and the Americas. Anti-retroviral treatments have been effective in preventing spread of the virus and active outbreaks of acquired immune deficiency syndrome (AIDS). However, the development and deployment of an effective vaccine would provide long-lasting protection and alleviate the need to depend heavily on prevention methods that require continued access and adherence.

Enhanced Immunogenicity Against HIV-1 Using a DNA-prime Poxvirus Vaccination

Researchers at the National Cancer Institute (NCI) have developed a method of stimulating an immune response in humans at risk for infection by, or already infected with, an Human Immunodeficiency Virus (HIV)-1 retrovirus. This method utilizes deoxyribonucleic acid (DNA) vaccines to stimulate CD8+ T cell immune responses. The DNA vaccine encodes antigens known to be effective against retroviruses, such as HIV-1gag, gp120, nefCTL, and proCTL. The same antigens are also expressed by the pox virus vaccine, which elicits an increased immune response when combined with the DNA vaccine.

Human Monoclonal Antibodies That Recognize Influenza A Viruses for Vaccine, Therapeutic, and Diagnostic Development

Human influenza A is one of two influenza virus types that cause seasonal epidemics of disease (known as flu season) almost every winter in the United States. Influenza A viruses are the only influenza viruses known to cause flu pandemics (i.e., global epidemics of flu disease). (Source.)

Hybridomas Producing Antibodies to Neuraminidase for Influenza A (H3N2) Diagnostics, Vaccine, and Therapeutic Development

Influenza A and B viruses can cause seasonal flu epidemics ― commonly known as the “flu season” ― and infect the nose, throat, eyes, and lungs in humans. Typically, flu seasons that are dominated by influenza A (H3N2) virus activity have higher associated hospitalizations and deaths in at-risk groups, such as people ages 65 and older and young children.