in vivo

(adjective)

Within a living organism.

Related Terms

Examples of in vivo in the following topics:

  • In Vivo Testing

    • In vivo testing using animal models of disease help discover new ways of solving complex health problems.
    • In vivo methods refer to the use of animals as a conduit to generate purified polyclonal antibody solutions (antiserum) for research purposes.
    • In vivo testing follows strict guidelines and humane animal use ethics.
    • In vivo testing remains a crucial step for the evaluation of in vitro experimental findings and the production of immunological solutions needed for the diagnosis of human diseases.
    • Animals are used in laboratory experiments to translate in vitro findings.

  • Tissue Engineering

    • These structures, typically called scaffolds , are often critical, both ex vivo as well as in vivo, to recapitulating the in vivo milieu and allowing cells to influence their own microenvironments.
    • Nanofiber Self-Assembly Molecular self-assembly is one of the few methods for creating biomaterials with properties similar in scale and chemistry to that of the natural in vivo extracellular matrix (ECM).
    • Moreover, these hydrogel scaffolds have shown superiority in in vivo toxicology and biocompatibility compared to traditional macroscaffolds and animal-derived materials.
    • In many cases, simple maintenance culture is not sufficient.
    • A bioreactor in tissue engineering, as opposed to industrial bioreactors, is a device that attempts to simulate a physiological environment in order to promote cell or tissue growth in vivo.

  • General Staining Methods

    • Staining is a technique used in microscopy to enhance contrast in a microscopic image.
    • In-vivo staining is the process of dyeing living tissue -- in vivo means "in life" (as contrasted to in-vitro staining).
    • There are an incredible number of stains that can be used in a variety of different methods.
    • In some cases, cells may be grown directly on a slide.
    • Live, in-vivo staining microscopy shares many of these steps, with the exception of fixation, which invariably kills the microbe to be examined.

  • Anticoagulants

    • However, if you are taking warfarin to prevent heart attacks, then it is necessary to control intake of leafy green vegetables since warfarin is an antagonist to vitamin K and could work improperly if the diet is high in vitamin K.
    • A group of pharmaceuticals called anticoagulants can be used in vivo as a medication for thrombotic (clotting) disorders including deep vein thrombosis, pulmonary embolism, myocardial infarction, and stroke.
    • Some anticoagulants are used in medical equipment such as test tubes, blood transfusion bags, and renal dialysis equipment.
    • Heparin can be used in vivo (by injection), and also in vitro to prevent blood or plasma clotting in or on medical devices.
    • Many other anticoagulants exist for use in research and development and as possible drug candidates or diagnostics.

  • Mapping Protein-Protein Interactions

    • In living organisms most of the biological functions are mediated by complex multi-component protein machineries and network activities.
    • Several methodologies exist to study the interaction of proteins in vivo.
    • The complete map of protein interactions that can occur in a living organism is called the interactome.
    • The yeast two-hybrid screening system is an effective and quick tool for the in vivo study of protein–protein interaction both in prokaryotes and eukaryotes.
    • In the absence of an interaction the domains remain distant, preventing a detectable output.

  • Ribosomes

    • Proteins synthesized in each of these locations serve a different role in the cell.
    • In prokaryotes, ribosomes can be found in the cytosol as well.
    • In most bacteria, the most numerous intracellular structure is the ribosome which is the site of protein synthesis in all living organisms.
    • In vivo assembly of the 30S subunit has two intermediates (p130S and p230S) and the 50S subunit has three intermediates (p150S, p250S, and p350S).
    • The intermediates in the in vivo assembly are precursor rRNA which is different from in vitro which uses matured rRNA.

  • Two-Hybrid Analysis

    • Several methodologies exist to study the interaction of proteins in vivo.
    • The yeast two-hybrid screening system is an effective and quick tool for the in vivo study of protein–protein interaction both in prokaryotes and eukaryotes.
    • In the absence of an interaction the domains remain distant, preventing a detectable output.
    • In the split-ubiquitin system, two integral membrane proteins to be studied are fused to two different ubiquitin moieties: a C-terminal ubiquitin moiety ("Cub", residues 35–76) and an N-terminal ubiquitin moiety ("Nub", residues 1–34).
    • In addition to being fused to an integral membrane protein, the Cub moiety is also fused to a transcription factor (TF) that can be cleaved off by ubiquitin specific proteases.

  • Dendritic Cells

    • Dendritic cells are present in lymphoid organs, the epithelia of the skin, the gastrointestinal and respiratory tracts, and in most parenchymal organs.
    • Most, called myeloid dendritic cells, are related in lineage to mononuclear phagocytes.
    • Mature dendritic cells reside in the T cell zones of the lymph nodes, and in this location they display antigens to T cells.
    • Dendritic cells are constantly in communication with other cells in the body.
    • For example, stimulating dendritic cells in vivo with microbial extracts causes the dendritic cells to rapidly begin producing interleukin 12 (IL-12).

  • Whole-Genome DNA-Binding Analysis

    • This has created a need for more efficient techniques to determine which parts of these sequences are bound in-vivo by the proteins controlling processes; such as gene expression, DNA replication and chromosomal mechanics.
    • The first step in the ChIP-Chip procedure is to fix protein-DNA interactions in living cells by chemical crosslinking.
    • In practice, formaldehyde is used in most ChIP-Chip experiments.
    • The two differentially-labeled DNAs are hybridized to the same microarray and the difference in fluorescence intensity gives a measure of the enrichment .

  • Electron Microscopy

    • An electron beam has an exceptionally short wavelength and can hit most objects in its path, increasing the resolution of the final image captured.
    • The electron beam is designed to travel in a vacuum to limit interference by air molecules.
    • TEM can project images in a much higher resolution—up to the atomic level of thinner objects.
    • It allows the visualization of microorganisms in three dimensions as the electrons are reflected when passed over the specimen.
    • observe individual viruses and macromolecular complexes in their natural biological context.