synchronization Protocols

Category: Cell Biology and Cell Culture: Cell Cycle Protocols

protocol describes a method for the synchronization of cell populations using centrifugal elutriation. The method relies on the fact that cell size increases linearly as cells proceed through the cell cycle. Cells of similar size (and cell cycle phase) are eluted stepwise from the cell chamber, with the smallest size (those in early G1) being eluted first. Using this procedure, it is possible to obtain relatively pure populations of cells at various points in G1, S, and G2/M. - [Read Cell Synchronization Using Centrifugal Elutriation Protocol]

Category: Cell Biology and Cell Culture: Flow Cytometry Protocols: Cell Cycle Analysis Protocols

This protocol describes a method for the synchronization of cell populations using centrifugal elutriation. The method relies on the fact that cell size increases linearly as cells proceed through the cell cycle. Cells of similar size (and cell cycle phase) are eluted stepwise from the cell chamber, with the smallest size (those in early G1) being eluted first. Using this procedure, it is possible to obtain relatively pure populations of cells at various points in G1, S, and G2/M. - [Read Cell Synchronization Using Centrifugal Elutriation Protocol]

Category: Cell Biology and Cell Culture: Cell Cycle Protocols: G Phase Protocols

This protocol provides a method for the synchronization of a monolayer culture of CHO cells in G1 using isoleucine deprivation. Since CHO cells can also be adapted to grow in suspension culture, this procedure can be used to obtain larger quantities of cells. When isoleucine is replaced, the cells resume growth and begin to enter S phase ~4 hours later. This method arrests almost 100% of the CHO cells in G1, and upon reversal, leads to rapid recovery of cell growth and very high cell viability. - [Read G1 Synchronization of CHO Cells by Isoleucine Deprivation Protocol]

Category: Cell Biology and Cell Culture: Flow Cytometry Protocols: Cell Cycle Analysis Protocols

This protocol provides a method for the synchronization of a monolayer culture of CHO cells in G1 using isoleucine deprivation. Since CHO cells can also be adapted to grow in suspension culture, this procedure can be used to obtain larger quantities of cells. When isoleucine is replaced, the cells resume growth and begin to enter S phase ~4 hours later. This method arrests almost 100% of the CHO cells in G1, and upon reversal, leads to rapid recovery of cell growth and very high cell viability. - [Read G1 Synchronization of CHO Cells by Isoleucine Deprivation Protocol]

Category: Cell Biology and Cell Culture: Cell Cycle Protocols: S Phase Protocols

This protocol provides a method for synchronizing cells at the G1/S border using a double treatment of thymidine, which, in excess, is an inhibitor of DNA synthesis. Cells are treated once with excess thymidine to accumulate the majority of them at G1/S; however, some cells will have stopped growth within the S phase. - [Read G1/S Phase Synchronization using Double Thymidine Synchronization Protocol]

Category: Cell Biology and Cell Culture: Flow Cytometry Protocols: Cell Cycle Analysis Protocols

This protocol provides a method for synchronizing cells at the G1/S border using a double treatment of thymidine, which, in excess, is an inhibitor of DNA synthesis. Cells are treated once with excess thymidine to accumulate the majority of them at G1/S; however, some cells will have stopped growth within the S phase. - [Read G1/S Phase Synchronization using Double Thymidine Synchronization Protocol]

Category: Cell Biology and Cell Culture: Cell Cycle Protocols: G Phase Protocols

This protocol provides a method for synchronizing cells at the G1/S border using a double treatment of thymidine, which, in excess, is an inhibitor of DNA synthesis. Cells are treated once with excess thymidine to accumulate the majority of them at G1/S; however, some cells will have stopped growth within the S phase. - [Read G1/S Phase Synchronization using Double Thymidine Synchronization Protocols]

Category: Cell Biology and Cell Culture: Cell Cycle Protocols: G Phase Protocols

This protocol uses the plant amino acid mimosine as a G1/S synchronizing agent. Cells are first treated with excess thymidine to accumulate the majority of them at G1/S; however, some cells will have stopped growth within the S phase. Thymidine is then removed to allow all the cells to proceed completely through the S phase. Mimosine is then added to arrest the cells at the G1/S border. When mimosine is removed, cells will begin to enter S phase within about 1 hour. - [Read G1/S Phase Synchronization Using Mimosine Arrest Protocol]

Category: Cell Biology and Cell Culture: Cell Cycle Protocols: S Phase Protocols

Protocol uses the plant amino acid mimosine as a G1/S synchronizing agent. Cells are first treated with excess thymidine to accumulate the majority of them at G1/S; however, some cells will have stopped growth within the S phase. Thymidine is then removed to allow all the cells to proceed completely through the S phase. Mimosine is then added to arrest the cells at the G1/S border. When mimosine is removed, cells will begin to enter S phase within about 1 hour. - [Read G1/S Phase Synchronization Using Mimosine Arrest Protocol]

Category: Cell Biology and Cell Culture: Flow Cytometry Protocols: Cell Cycle Analysis Protocols

This protocol uses the plant amino acid mimosine as a G1/S synchronizing agent. Cells are first treated with excess thymidine to accumulate the majority of them at G1/S; however, some cells will have stopped growth within the S phase. Thymidine is then removed to allow all the cells to proceed completely through the S phase. Mimosine is then added to arrest the cells at the G1/S border. When mimosine is removed, cells will begin to enter S phase within about 1 hour. - [Read G1/S Phase Synchronization Using Mimosine Arrest Protocol]

Category: Cell Biology and Cell Culture: Cell Cycle Protocols: Mitosis Protocols

Protocol describes a method for synchronizing monolayer cells in mitosis using selective detachment from their substrate. During mitosis, cells become spherical, causing them to become more loosely attached to their substrate. The "rounded up" cells are selectively detached by tapping the culture flask, resulting in a population in which as many as 90-98% of the cells are in mitosis. The drug nocodazole is used to increase the percentage of cells undergoing mitosis before detachment is performed - [Read Synchronization of Mammalian Cell Cultures in Mitosis Using Selective Detachment Protocol]

Category: Cell Biology and Cell Culture: Flow Cytometry Protocols: Cell Cycle Analysis Protocols

This protocol describes a method for synchronizing monolayer cells in mitosis using selective detachment from their substrate. During mitosis, cells become more spherical, causing them to become more loosely attached to their substrate. The "rounded up" cells are selectively detached by tapping the culture flask, resulting in a population in which as many as 90-98% of the cells are in mitosis. The drug nocodazole is used to increase the percentage of cells undergoing mitosis before detachment.. - [Read Synchronization of Mammalian Cell Cultures in Mitosis Using Selective Detachment Protocol]