Strategies for "minimal growth maintenance" of cell cultures: a perspective on management for extended duration experimentation in the microgravity environment of a space station

How cells manage without gravity and how they change in the absence of gravity are basic questions that only prolonged life on a Space station will enable us to answer. We know from investigations carried out on various kinds of Space vehicles and stations that profound physiological effects can and...

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Veröffentlicht in:	The Botanical review 1996-01, Vol.62 (1), p.41-108
1. Verfasser:	Krikorian, A.D. (State University of New York at Stony Brook, Stony Brook, NY.)
Format:	Artikel
Sprache:	eng
Schlagworte:	BESOIN EN OXYGENE Bioreactors Botany Cell culture Cell culture techniques Cell Culture Techniques - methods Cell growth Cell Physiological Phenomena Cells Cellular biology CELLULE CELULAS CRECIMIENTO CROISSANCE Cryopreservation CULTIVO DE CELULAS CULTURE DE CELLULE Culture Media Cultured cells EXPERIMENTACION EXPERIMENTATION FISIOLOGIA VEGETAL GRAVIDEZ GRAVITE Gravity INHIBIDORES DEL CRECIMIENTO INHIBITEUR DE CROISSANCE Life Sciences (General) Microgravity PHYSIOLOGIE VEGETALE Plant Cells Plant Development Plant growth Plant tissues Plants Plants - embryology PRESION OSMOTICA PRESSION OSMOTIQUE REQUERIMIENTO DE OXIGENO Space biology Space Flight Space life sciences TEMPERATURA TEMPERATURE Tissue culture Weightlessness
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container_title	The Botanical review
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creator	Krikorian, A.D. (State University of New York at Stony Brook, Stony Brook, NY.)
description	How cells manage without gravity and how they change in the absence of gravity are basic questions that only prolonged life on a Space station will enable us to answer. We know from investigations carried out on various kinds of Space vehicles and stations that profound physiological effects can and often do occur. We need to know more of the basic biochemistry and biophysics both of cells and of whole organisms in conditions of reduced gravity. The unique environment of Space affords plant scientists an unusual opportunity to carry out experiments in microgravity, but some major challenges must be faced before this can be done with confidence. Various laboratory activities that are routine on Earth take on special significance and offer problems that need imaginative resolution before even a relatively simple experiment can be reliably executed on a Space station. For example, scientists might wish to investigate whether adaptive or other changes that have occurred in the environment of Space are retained after return to Earth-normal conditions. Investigators seeking to carry out experiments in the low-gravity environment of Space using cultured cells will need to solve the problem of keeping cultures quiescent for protracted periods before an experiment is initiated, after periodic sampling is carried out, and after the experiment is completed. This review gives an evaluation of a range of strategies that can enable one to manipulate cell physiology and curtail growth dramatically toward this end. These strategies include cryopreservation, chilling, reduced oxygen, gel entrapment strategies, osmotic adjustment, nutrient starvation, pH manipulation, and the use of mitotic inhibitors and growth-retarding chemicals. Cells not only need to be rendered quiescent for protracted periods but they also must be recoverable and further grown if it is so desired
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(State University of New York at Stony Brook, Stony Brook, NY.)</creatorcontrib><title>Strategies for "minimal growth maintenance" of cell cultures: a perspective on management for extended duration experimentation in the microgravity environment of a space station</title><title>The Botanical review</title><addtitle>Bot Rev</addtitle><description>How cells manage without gravity and how they change in the absence of gravity are basic questions that only prolonged life on a Space station will enable us to answer. We know from investigations carried out on various kinds of Space vehicles and stations that profound physiological effects can and often do occur. We need to know more of the basic biochemistry and biophysics both of cells and of whole organisms in conditions of reduced gravity. The unique environment of Space affords plant scientists an unusual opportunity to carry out experiments in microgravity, but some major challenges must be faced before this can be done with confidence. Various laboratory activities that are routine on Earth take on special significance and offer problems that need imaginative resolution before even a relatively simple experiment can be reliably executed on a Space station. For example, scientists might wish to investigate whether adaptive or other changes that have occurred in the environment of Space are retained after return to Earth-normal conditions. Investigators seeking to carry out experiments in the low-gravity environment of Space using cultured cells will need to solve the problem of keeping cultures quiescent for protracted periods before an experiment is initiated, after periodic sampling is carried out, and after the experiment is completed. This review gives an evaluation of a range of strategies that can enable one to manipulate cell physiology and curtail growth dramatically toward this end. These strategies include cryopreservation, chilling, reduced oxygen, gel entrapment strategies, osmotic adjustment, nutrient starvation, pH manipulation, and the use of mitotic inhibitors and growth-retarding chemicals. Cells not only need to be rendered quiescent for protracted periods but they also must be recoverable and further grown if it is so desired</description><subject>BESOIN EN OXYGENE</subject><subject>Bioreactors</subject><subject>Botany</subject><subject>Cell culture</subject><subject>Cell culture techniques</subject><subject>Cell Culture Techniques - methods</subject><subject>Cell growth</subject><subject>Cell Physiological Phenomena</subject><subject>Cells</subject><subject>Cellular biology</subject><subject>CELLULE</subject><subject>CELULAS</subject><subject>CRECIMIENTO</subject><subject>CROISSANCE</subject><subject>Cryopreservation</subject><subject>CULTIVO DE CELULAS</subject><subject>CULTURE DE CELLULE</subject><subject>Culture Media</subject><subject>Cultured cells</subject><subject>EXPERIMENTACION</subject><subject>EXPERIMENTATION</subject><subject>FISIOLOGIA VEGETAL</subject><subject>GRAVIDEZ</subject><subject>GRAVITE</subject><subject>Gravity</subject><subject>INHIBIDORES DEL CRECIMIENTO</subject><subject>INHIBITEUR DE CROISSANCE</subject><subject>Life Sciences (General)</subject><subject>Microgravity</subject><subject>PHYSIOLOGIE VEGETALE</subject><subject>Plant Cells</subject><subject>Plant Development</subject><subject>Plant growth</subject><subject>Plant tissues</subject><subject>Plants</subject><subject>Plants - embryology</subject><subject>PRESION OSMOTICA</subject><subject>PRESSION OSMOTIQUE</subject><subject>REQUERIMIENTO DE OXIGENO</subject><subject>Space biology</subject><subject>Space Flight</subject><subject>Space life sciences</subject><subject>TEMPERATURA</subject><subject>TEMPERATURE</subject><subject>Tissue culture</subject><subject>Weightlessness</subject><issn>0006-8101</issn><issn>1874-9372</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>1996</creationdate><recordtype>article</recordtype><sourceid>CYI</sourceid><sourceid>EIF</sourceid><recordid>eNqN0kFv0zAUAOAIgdgYXDgihKwdEEIr2K4T29zGxMakiUmUnS03ec48JXZnO2X7W_xC3KWiKuphyiFK3veek_deUbwm-BPBmH_-eoqpqISk-EmxTwRnEznl9GmxjzGuJoJgsle8iPEGY0IkF8-LPUJKhrFk-8WfWQo6QWshIuMDOuyts73uUBv873SNem1dAqddDYfIG1RD16F66NIQIH5BGi0gxAXUyS4BeZe90y304NJDObjLyQ00qBnyMTYDuMsZdgXGZ-tQugbU2zr4NuilTfcI3NIG7x6q5DM1igtdA4pjysvimdFdhFfr-0Fxdfrt18n3ycXl2fnJ8cWkLgVNk4pxOW-gnFLa1BI3pagqzudQC2bAcEE4x5yzOWuE0QKTqTFSEmCl1IZRzacHxfux7iL42wFiUr2Nq__XDvwQFc-d5liu4OF_8MYPweVvU5TkeVSCVBkdjajVHSjrjM-Nr1twEHTnHRibXx8TQStaliTzyQ6erwZyq3b5D1s-k5Sb3-ohRnU--_l4-uOxVJxdbNGjXbT2XQctqDyZk8st_nHkeewxBjBqkbdCh3tFsFpttdpsdcbv1g0e5j00G7pe4wzejsDpqJVLIXce4xwTkslqE76JyYd_6WxaMlqVOfxmDBvtlW6DjepqJitKGSXTv_ruCu0</recordid><startdate>199601</startdate><enddate>199601</enddate><creator>Krikorian, A.D. 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Investigators seeking to carry out experiments in the low-gravity environment of Space using cultured cells will need to solve the problem of keeping cultures quiescent for protracted periods before an experiment is initiated, after periodic sampling is carried out, and after the experiment is completed. This review gives an evaluation of a range of strategies that can enable one to manipulate cell physiology and curtail growth dramatically toward this end. These strategies include cryopreservation, chilling, reduced oxygen, gel entrapment strategies, osmotic adjustment, nutrient starvation, pH manipulation, and the use of mitotic inhibitors and growth-retarding chemicals. Cells not only need to be rendered quiescent for protracted periods but they also must be recoverable and further grown if it is so desired</abstract><cop>Ames Research Center</cop><pub>New York Botanical Garden</pub><pmid>11540094</pmid><doi>10.1007/BF02868920</doi><tpages>68</tpages></addata></record>
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subjects	BESOIN EN OXYGENE Bioreactors Botany Cell culture Cell culture techniques Cell Culture Techniques - methods Cell growth Cell Physiological Phenomena Cells Cellular biology CELLULE CELULAS CRECIMIENTO CROISSANCE Cryopreservation CULTIVO DE CELULAS CULTURE DE CELLULE Culture Media Cultured cells EXPERIMENTACION EXPERIMENTATION FISIOLOGIA VEGETAL GRAVIDEZ GRAVITE Gravity INHIBIDORES DEL CRECIMIENTO INHIBITEUR DE CROISSANCE Life Sciences (General) Microgravity PHYSIOLOGIE VEGETALE Plant Cells Plant Development Plant growth Plant tissues Plants Plants - embryology PRESION OSMOTICA PRESSION OSMOTIQUE REQUERIMIENTO DE OXIGENO Space biology Space Flight Space life sciences TEMPERATURA TEMPERATURE Tissue culture Weightlessness
title	Strategies for "minimal growth maintenance" of cell cultures: a perspective on management for extended duration experimentation in the microgravity environment of a space station
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