A method of performing a clinical trial for a gene editing or gene excising system for treating HIV in humans, by recruiting HIV infected individuals currently receiving highly active antiretroviral therapy (HAART) that is effective in lowering viral load and entering qualified individuals as participants in a clinical trial, administering the gene editing or gene excising system treatment to the participants in Phase 1a, Phase 1b, and Phase 1c, and performing assays to confirm HIV viral genome excision from the participants' cells. A method of performing a clinical trial for a gene editing or gene excising system for treating a latent viral infection in humans.

HIV-1's ability to enter a transcriptionally dormant state and establish a reservoir of latently infected cells is considered the major barrier to eradicating the virus from infected patients. Stochastic noise (i.e. fluctuations) in an HIV-1 transcriptional positive-feedback loop is one mechanism that enables HIV-1 to establish latency. Here, Applicants demonstrate that small-molecule modulation of noise in HIV-1 gene expression radically perturbs HIV-1 latency.

The invention principally relates to a method of detecting a disease agent in blood, comprising: (i) creating a sample infra-red spectrum representative of the blood, with one or more spectral components, each having a wavenumber and absorbance value; (ii) providing a reference database of spectral models, each model having one or more database spectral components of a wavenumber and an absorbance value, wherein the database spectral components identify disease agents; (iii) determining whether one or more database spectral components corresponds to one or more sample spectral components, and (iv) compiling a list of corresponding database components identified.

The present invention relates, in general, to human immunodeficiency virus (HIV), and, in particular, to a vaccine for HIV-1, comprising synthetic V3 glycopeptides, and to methods of making and using same.

The present invention relates to cupredoxin, specifically Pseudomonas aeruginosa azurin, and/or Pseudomonas aeruginosa cytochrome c.sub.551 and their use in inhibiting of viral infection, and in particular infection of mammalian cells by the Human Immunodeficiency Virus (HIV). The invention also relates to variants and derivatives of cupredoxin and cytochrome c that retain the ability to inhibit viral infection, and in particular infection by the Human Immunodeficiency Virus (HIV). The invention also relates to research methods for studying viral and bacterial infection in mammalian cells.

Embodiments herein provide methods for identifying antibody glycosylation profiles which correlate with antibody effector functions. These profiles are antibody signatures for the respective correlated antibody effector functions, and are incorporated into engineered antibody for antibody-mediated treatments of infections, diseases, and medical conditions.

Certain R5 virus tropic HIV-1 subjects with viral load effectively conventionally controlled using HAART, i.e., subject having less than 50 viral copies/mL (<50 cp/mL), may be substantially more susceptible than others to effective monotherapy treatment using anti-CCR5 agents, e.g, PRO 140 mAbs. Certain HIV-1 subjects using PRO 140 monotherapy treatment may experience prolonged or unlimited time periods with actual undetectable viral loads, extremely low viral load counts 1 cp/mL, very low, or low levels, or at conventionally undetectable levels, during monotherapy. Increasing dose amounts of anti-CCR5 agents, e.g., PRO 140, from 350 mg to 525 mg or 700 mg, may beneficially suppress a subject's viral load count before, during, and/or maintain effective prolonged monotherapy and may shorten the period of time necessary to determine if a subject will respond positively to PRO 140 monotherapy to less than eight (8) weeks. This invention includes protocols, methods, and kits.

A solution is described for preserving cells and/or extra-cellular components in naturally expressed bodily fluids (e.g. saliva, sputum, urine) for further downstream analysis and/or for diagnosis of a medical condition. The solution may be hypertonic with respect to blood. Techniques are described for enriching cells from a sample of a naturally expressed bodily fluid, and/or for analysis, e.g. to diagnose medical conditions such as cancer, obesity, infections, autism, Alzheimer disease, hetotological disorders, cardiovascular disease or disorders, diabetes, vulnerable plack, LTBI, HIV infection, COPD, ACQS.

Methods of calibrating ELISA read-out for clinical antibody response are described. In particular, the invention relates to methods for calibrating ELISA read-out for the clinical antibody response to vaccines by quantitative mass spectrometry.

A nanoplasmonic platform can be used for the detection and quantification of multiple HIV subtypes in whole blood with localized surface plasmon resonance. Among other things, this nanoplasmonic platform provides a viable way to detection and quantification of viral load at a point of care with significantly less cost, time, and laboratory resources than existing methods of detection. Although an example of HIV detection in whole blood is provided, the nanoplasmonic platform is adaptable to detect other pathogens and infectious agents or macromolecules.