Microphysiometry is the in vitro micro-measurement of the functions and activities of life or of living matter (as organs, tissues, or cells) and of the physical and chemical phenomena involved on a very small micrometer (μm) scale.[1][2] The term microphysiometry emerged in the scientific literature at the end of the 1980s.[3][4]

The primary parameters assessed in microphysiometry comprise pH and the concentration of dissolved oxygen, glucose, and lactic acid, with an emphasis on the first two. Measuring these parameters experimentally in combination with a fluidic system for cell culture maintenance and a defined application of drugs or toxins provides three quantitative output parameters: extracellular acidification rates (EAR), oxygen uptake rates (OUR), and rates of glucose consumption or lactate release that characterize the metabolic situation.

Due to the label-free nature of sensor-based measurements, dynamic monitoring of cells or tissues for several days or even longer is feasible.[5] On an extended timescale, a dynamic analysis of a cell's metabolic response to an experimental treatment can distinguish acute effects (e.g., one hour after a treatment), early effects (e.g., at 24 hours), and delayed, chronic responses (e.g., at 96 hours). As stated by Alajoki et al., "The concept is that it is possible to detect receptor activation and other physiological changes in living cells by monitoring the activity of energy metabolism".[6]

See also

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References

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  1. ^ McConnel HM, Owicki JC, Parce JW, Miller DL, Baxter GT, Wada HG, Pitchford S (1992). "The Cytosensor Microphysiometer: Biological Applications of Silicon Technology", Science, 257, 1906-1912
  2. ^ Brischwein, M.; Wiest, J. (2018). "Microphysiometry". Bioanalytical Reviews. 2. Springer: 163–188. doi:10.1007/11663_2018_2. ISBN 978-3-030-32432-2.
  3. ^ Hafeman DG, Parce JW, McConnell H (1988). "Light-addressable potentiometric sensor for biochemical systems", Science 240, 1182–1185
  4. ^ Owicki JC, Parce JW (1990). "Bioassays with a microphysiometer". Nature 344, 271–272
  5. ^ Wiest, J. (2022). "Systems engineering of microphysiometry". Organs-on-a-Chip. 4. Elsevier B.V. doi:10.1016/j.ooc.2022.100016.
  6. ^ Alajoki ML, Bayter GT, Bemiss WR, Blau D, Bousse LJ, Chan SDH, Dawes TD, Hahnenberger KM, Hamilton JM, Lam P, McReynolds RJ, Modlin DN, Owicki C, Parce JW, Redington D, Stevenson K, Wada HG, Williams J (1997). "High-performance microphysiometry in drug discovery", Devlin JP (ed) High Throughput Screening: The Discovery of Bioactive Substances. Marcel Dekker, New York, 427–442.

📚 Artikel Terkait di Wikipedia

Cellular respiration

respiration: maintenance as a functional component of cellular respiration Microphysiometry Pasteur point Respirometry: research tool to explore cellular respiration

Metabolism

disease hindering the body's ability to process and distribute nutrients Microphysiometry Primary nutritional groups – Group of organisms Proto-metabolism –

Organ-on-a-chip

limits the inferences that can be drawn. Many aspects of subsequent microphysiometry aim to address these constraints by modeling more sophisticated physiological

Tissue culture

capability to differentiate to any other cell. Cell culture Cultured meat Microphysiometry Organ culture Plant tissue culture Carrel, Alexis and Montrose T. Burrows

Biochip

quantify the individual analytes. Biochips are also used in the field of microphysiometry e.g. in skin-on-a-chip applications. For details about other array

Animal testing

psychoactive drugs on animals Human subject research Krogh's principle Microphysiometry The People's Petition Preclinical imaging Remote control animal Sentinel

Lab-on-a-chip

antigen-antibody reactions. Ion channel screening (patch clamp) Microfluidics Microphysiometry Organ-on-a-chip Real-time PCR: detection of bacteria, viruses and cancers

Electric cell-substrate impedance sensing

on cell monolayers". Progress in Biophysics and Molecular Biology. 199: 246–254. doi:10.1016/j.pbiomolbio.2026.02.002. PMID 41644065. Microphysiometry