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The Corona virus disease, 2019 (COVID-19) pandemic is a worldwide public health crisis with over 153 million confirmed cases and 3.2 million deaths as of April 2021. COVID-19 is caused by a novel coronavirus called SARS-CoV-2. SARS-COV-2 infects hosts via its spike (S) protein, which has two portions, S1 that binds the cell and S2 that is involved in viral entry via fusion with the cell membrane. There are several vaccines available for COVID-19 patients that directly target SARS-CoV-2 by systemic immunization.

Computer and imaging technologies led to the development of digital pathology and the capture and storage of pathological specimens as digitally formatted images. The use of artificial intelligence (AI) in digital pathology, such as in three-dimensional (3D) reconstruction, requires analyses of high volumes of data. This resulted in increased demands for processing and acquisition of digital images of pathology samples. Increased usage cannot be met by the time-consuming, manual, and laborious methods currently used.

Bioluminescence imaging with luciferin-luciferase pairs is a well-established technique for tracking cells and other biological features in animal models. Bioluminescent is a chemical process which does not require an external input for excitation. Bioluminescent imaging is often limited to monitoring single processes in vivo due to the lack of distinguishable probes. Additionally, existing probes typically operate with light in the visible range, which is highly scattered and exhibits poor tissue penetration. 

This technology describes additional methods of using the griffithsin anti-viral polypeptides described in related NCI invention (reference number E-106-2003).  Specifically, this invention describes the use of GRFT to inhibit viral infection of hepatitis C viral infection, a severe acute respiratory syndrome (SARS) viral infection, an H5N1 viral infection, or an Ebola viral infection. 

Virus entry into a susceptible host cell is the first step in the formation of all viral diseases. Controlling viral infections by disrupting viral entry is advantageous for antibody-mediated neutralization by the host’s immune system and as a preventive and therapeutic antiviral strategy. Plant-derived carbohydrate-binding proteins (lectins) have emerged as a new class of antiviral biologics by taking advantage of a unique glycosylation pattern only found on the surface of viruses.

Adoptive T-cell therapy (ACT) utilizes tumor-reactive T cells to induce disease remission. While ACT has been used effectively to treat metastatic melanoma and certain epithelial cancers, most patients do not respond to treatment. Although the mechanisms underlying this variable response to therapy are not fully elucidated, the phenotype of the adoptively transferred cell is known to be a key determinant of treatment efficacy.

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.

Several viral epidemics – such as the epidemics caused by H1N1 influenza virus, human immunodeficiency virus (HIV), Ebola virus, Zika virus, severe acute respiratory syndrome (SARS) virus, Middle East respiratory syndrome (MERS) virus and SARS-CoV-2 – have profoundly impacted global human health. Early identification of infected and/or infectious persons and isolating them from the population are some of the most effective and evident measures to prevent human-to-human spreading.

Hydrogels represent an attractive controlled drug-delivery system that have been used in various clinical applications, such as: tissue engineering for wound healing, surgical procedures, pain management, cardiology, and oncology. High-water content of hydrogels confers tissue-like physical properties and the crosslinked fibrillar network enables encapsulation of labile small molecule drugs, peptides, proteins, nucleic acids, proteins, nanoparticles, or cells.

Nanoparticles such as lipid-based nanoparticles (LNPs) represent a relatively new era of targeted drug delivery systems wherein these biocompatible particles can carry the drug(s) of interest to a specific tumor site. The new generation of nanoparticles, known as stealth nanoparticles, are engineered to have a coating of polyethylene glycol polymer (PEG) or other glycolipids that enable them to evade the immune system and have a longer circulation lifespan as well as improved bioavailability to diseased tissue and reduced non-specific toxicity.