Use of Hoechst 33342 for cell selection from multicell systems.
about
Multizone paper platform for 3D cell culturesA new UV-visible confocal laser scanning microspectrofluorometer designed for spectral cellular imaging.In vivo radioprotection of mouse brain endothelial cells by Hoechst 33342.Cross-linking of histone proteins to DNA by UV illumination of chromatin stained with Hoechst 33342.DNA ligands as radioprotectors: molecular studies with Hoechst 33342 and Hoechst 33258.The action of epidermal growth factor (EGF) is limited to specific phases of the cell cycle in an EGF dependent colonic cell line.A microfluidic system for investigation of extravascular transport and cellular uptake of drugs in tumors.Tissue electroporation: quantification and analysis of heterogeneous transport in multicellular environmentsEffect of vascular marker Hoechst 33342 on tumour perfusion and cardiovascular function in the mouse.Paper-supported 3D cell culture for tissue-based bioassays.Comparison of fluorescence intensity of Hoechst 33342-stained EMT6 tumour cells and tumour-infiltrating host cellsCharacterization of a carbocyanine derivative as a fluorescent penetration probe.Radiation sensitivity of tumour cells stained in vitro or in vivo with the bisbenzimide fluorochrome Hoechst 33342.Cell selection from a murine tumour using the fluorescent probe Hoechst 33342Cell killing and DNA damage by etoposide in Chinese hamster V79 monolayers and spheroids: influence of growth kinetics, growth environment and DNA packaging.Regulation of intracellular pH in subpopulations of cells derived from spheroids and solid tumours.Pharmacokinetics, binding and distribution of Hoechst 33342 in spheroids and murine tumours.Effects of agents which inhibit the regulation of intracellular pH on murine solid tumoursUse of a tritiated thymidine suicide technique in the study of the cytotoxic drug response of cells located at different depths within multicellular spheroids.Chemosensitization by misonidazole in CCNU-treated spheroids and tumoursResponse of spheroids implanted in the peritoneal cavity of mice exposed to cyclophosphamide and ionizing radiationThe biological activity of cisplatin and dibromodulcitol in combination therapy.Hydroethidine: a fluorescent redox probe for locating hypoxic cells in spheroids and murine tumours.Radioprotection by DNA ligands.Patterns of mutagen binding and penetration in multicell spheroids.Viable sorting of intact multicellular spheroids by flow cytometry.The effects of melphalan and misonidazole on the vasculature of a murine sarcoma.Fluorescence studies of Hoechst 33342 with supercoiled and relaxed plasmid pBR322 DNA.An ultra-pure in vitro phase synchrony method employing centrifugal elutriation and viable flow cytometric cell sorting.Use of flow cytometry in the measurement of cell mitotic cycle.Real-time cell cycle imaging during melanoma growth, invasion, and drug response.Cellular heterogeneity in human epithelial neoplasms.Photochemically enhanced adenoviral transduction in a multicellular environment.Drug and radiation resistance in spheroids: cell contact and kinetics.Characterization of DNA-strand breakage induced in V79 cells by F 11782, a catalytic inhibitor of topoisomerases.Proton NMR microscopy of multicellular tumor spheroid morphology.Radiosensitisation and radioprotection by BSO and WR-2721: the role of oxygenation.Factors that influence the penetration of methotrexate through solid tissue.Automated selective dissociation of cells from different regions of multicellular spheroids.Regrowth kinetics of cells from different regions of multicellular spheroids of four cell lines.
P2860
Q28740410-44E90E79-D537-42C9-9418-7663B8DD8FEEQ30675030-678A2062-69C4-4F51-B0AA-4657378A3379Q33181737-D5F19221-E354-4067-9770-F56C478F44C4Q33187800-998BBC23-5185-4DFC-8977-76A8ACC55B99Q33190004-7CD185A6-2894-470C-ACA6-9194347FEB59Q33583994-20809B98-6E7D-4BC7-8053-B81319323AA9Q34085441-AFC48E18-794A-4A1E-9BA7-B971CFEB6F7FQ34185762-8E774959-0DD1-43FC-9CA9-DF40BF18FBD5Q34263859-81762D53-475D-469C-B6E3-7C89188C9D51Q35008942-AFD33FC2-EB8F-4A56-B757-C3660660310DQ35086548-05A72D8F-B179-4073-9DAA-161E09ABA1E7Q35086566-E1982E79-FC81-46B2-B33C-BCA386054A83Q35159806-833CE28C-8C9C-4AFF-ADAA-F1B24A29BCCBQ35583255-2A3DBD1B-FE59-467F-B043-3FB50D2C6460Q35976079-D9C5ADF6-1053-4CA3-9F1C-6DF0455154D7Q35977837-6869634B-D520-4B88-8CCC-F8CA9D2EA075Q35992563-CC29670C-DDEF-4434-B10F-4DB2667891FEQ35994216-C265D21F-BDAE-4131-8BB2-33048B9A6A8AQ36027961-34EE8483-CAD6-4C0D-AC50-CFD2B1DD2CCBQ36028986-51666A7A-3F95-46B3-8DE1-C0FC83A2096EQ36029068-92264F13-5DF9-41EB-AB8D-8751FCEE5419Q36080384-561BB7CB-A23F-43A8-BD96-602EF0EBD1C5Q36207258-5967253C-449A-4355-8FE9-396B2814365AQ36291869-4153CC56-DF57-4A25-B2CB-5231F1FD75DCQ36430927-B4387317-6C2E-4EE7-B86A-F8B44D7B1F25Q36446673-23E12D63-AA9F-446D-A430-6E2773CEB799Q36464321-2C800F2F-0788-4689-8B62-A6A53A2F21D4Q36495293-1A69743A-C57E-4D57-9B45-0566D4B0B7A9Q36612315-E0300403-0706-4D39-90ED-E92FC968B5CBQ38168365-4F194550-9697-4994-BDC4-6F249B48A479Q38987861-C6063F5A-D12E-433C-9CFE-4E36C5E1484FQ39654741-80C803F8-DCB0-4F2E-AF0F-1A411564E976Q40296872-7864D17E-976E-439D-9760-B206467B990CQ40630918-938C1C90-7058-4856-85AD-2977524F597DQ40839116-57A5DF59-0BF7-40AC-B3D3-5F5CAD47FB23Q41713344-A55F6FC9-1AC3-4A53-84C8-AD687B0EAB93Q43051036-E1A3B0FF-E3BD-43E7-821F-7373903BA525Q43517179-D4246D33-446F-4C40-A4B3-1DB49293AD0DQ43598143-CF6FFCDC-76F2-4FE9-AC32-40FDC52AA3DEQ43711507-4E44B644-1413-4029-80EF-AEAA8D1BE1D6
P2860
Use of Hoechst 33342 for cell selection from multicell systems.
description
1982 nî lūn-bûn
@nan
1982年の論文
@ja
1982年論文
@yue
1982年論文
@zh-hant
1982年論文
@zh-hk
1982年論文
@zh-mo
1982年論文
@zh-tw
1982年论文
@wuu
1982年论文
@zh
1982年论文
@zh-cn
name
Use of Hoechst 33342 for cell selection from multicell systems.
@ast
Use of Hoechst 33342 for cell selection from multicell systems.
@en
type
label
Use of Hoechst 33342 for cell selection from multicell systems.
@ast
Use of Hoechst 33342 for cell selection from multicell systems.
@en
prefLabel
Use of Hoechst 33342 for cell selection from multicell systems.
@ast
Use of Hoechst 33342 for cell selection from multicell systems.
@en
P356
P1476
Use of Hoechst 33342 for cell selection from multicell systems.
@en
P2093
R E Durand
P304
P356
10.1177/30.2.6174559
P577
1982-02-01T00:00:00Z