Targeted removal of blood cancer cells from mixed cell populations by cell recognition with matching particle imprints

Das, Anupam A.K.; Remaud, Perrine; Medlock, Jevan; Das, Anupam A. K.; Allsup, David J.; Madden, Leigh A.; Nees, Dieter; Weldrick, Paul J.; Paunov, Vesselin N.

doi:10.1039/c9qm00531e

All Outputs (3)

Novel Synthesis Methods For the Production of Human Circulating Metabolites of Natural Products (2024)
Thesis
Doyle, B. (2023). Novel Synthesis Methods For the Production of Human Circulating Metabolites of Natural Products. (Thesis). University of Hull. Retrieved from https://hull-repository.worktribe.com/output/4587910

Upon entering the body, any given xenobiotic can undergo metabolism which facilitates its excretion from the body. When metabolised, a compound typically has the same effects of the initial drug/nutraceutical, however this is not always the case and... Read More about Novel Synthesis Methods For the Production of Human Circulating Metabolites of Natural Products.

Advanced biomedical applications of cell clusteroids based on aqueous twophase Pickering emulsion systems (2022)
Thesis
Wang, A. (2022). Advanced biomedical applications of cell clusteroids based on aqueous twophase Pickering emulsion systems. (Thesis). University of Hull. Retrieved from https://hull-repository.worktribe.com/output/4249064

The development of in vitro models for advancing the research of cell biology and cell physiology is of great importance to the fields of biotechnology, cancer study, drug testing, toxicity study. The emerging field includes tissue engineering and re... Read More about Advanced biomedical applications of cell clusteroids based on aqueous twophase Pickering emulsion systems.

Targeted removal of blood cancer cells from mixed cell populations by cell recognition with matching particle imprints (2019)
Journal Article
Das, A. A., Remaud, P., Medlock, J., Das, A. A. K., Allsup, D. J., Madden, L. A., …Paunov, V. N. (2019). Targeted removal of blood cancer cells from mixed cell populations by cell recognition with matching particle imprints. Materials Chemistry Frontiers, 4(1), 197-205. https://doi.org/10.1039/c9qm00531e

We report a new approach for separation of blood cancer cells from healthy white blood cells based on cell recognition by surface functionalised particle imprints. We prepared polymeric particle imprints from a layer of suspension of monodisperse PMM... Read More about Targeted removal of blood cancer cells from mixed cell populations by cell recognition with matching particle imprints.