What is the Best Time to Split Cells?

  • Thread starter Goodie
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In summary, splitting cells at their mid log phase is important for optimal transfection. The split ratio should be determined based on the cell type, with some cells needing to be split more often due to their dependence on growth factors. It is generally recommended to split cells 24 hours before transfection and to aim for 50% confluency for cells that grow attached to the plate. However, for cells in suspension, it does not matter as much as they will continue to grow regardless. Confluency levels of 80-90% are typically considered to be at mid log phase, while 100% confluency indicates end log phase. These are rough estimates and can vary depending on the cell type and transfection methods used.
  • #1
Goodie
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Should I always split my cells at their mid log phase? Or does it only matter at transfection? How do I know that my cells are in the mid log phase? How do i know that my cells are 80-100% confluence? Is this 80-100% a rough estimation or accurately done?

Thanks.
 
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  • #2
Its all rough estimates, 80-100% means usually a full dish of cells, depending on the transfection methods and the cell lines used the general idea is that cells need to be around 50% confluent and preferably not in colonies for optimal transfection. I usually split my cells 24 hours before transfection.
 
  • #3
So when my flask is confluent then my cells are at the mid log phase? The split ratio is usually 1/2 to 1/20. What decides which factor we should use? :rolleyes:
 
  • #4
nope, the general idea about splitting at mid log phase is that the cells keep dividing while if you thake em at end log phase (confluent dish) the cells have stopped because they ran out of space and have to re-enter the cell cycle which presumably takes a long time (depending on cell type). So its faster if you need many cells. Personally I think this is bullocks because treating the cells with trypsin will also stop them. This then only holds true for cells in suspension and there they don't run out of space but rather out of nutrients.

If you want to know the factor I need to know the cell type... a full dish of primary human fibroblasts will stop cycling if you split them more than 1/4 while transformen human embryonic kindey cells can go 1/15 without any problem.
 
  • #5
Sho'Nuff said:
nope, the general idea about splitting at mid log phase is that the cells keep dividing while if you thake em at end log phase (confluent dish) the cells have stopped because they ran out of space and have to re-enter the cell cycle which presumably takes a long time (depending on cell type). So its faster if you need many cells. Personally I think this is bullocks because treating the cells with trypsin will also stop them.
So does it mean that a 80-90% confluence is most probably at mid log phase and 100% confluent is at end log phase?

Sho'Nuff said:
This then only holds true for cells in suspension and there they don't run out of space but rather out of nutrients.
What do you mean?

Sho'Nuff said:
If you want to know the factor I need to know the cell type... a full dish of primary human fibroblasts will stop cycling if you split them more than 1/4 while transformen human embryonic kindey cells can go 1/15 without any problem.
For example why one splits a flask into two new flasks (split ratio 1/2) instead of 4 new flasks (1/4) ? Is that the amount of cells one needs that also decide it? :rolleyes:

Thanks.
 
  • #6
Goodie said:
So does it mean that a 80-90% confluence is most probably at mid log phase and 100% confluent is at end log phase?

no at 80-90% most of the cells have reached confluency and some are still dividing so if the whole dish is viewed this would be near end log phase. at 100% all the cells have stopped

at 50% confluency most of the cells will still be growing so since most of the cells are now in log phase the plate can be regarded as being in log phase. mid log phase is when most cells on the plate are dividing (so at 50% or so) but note that the individual cells do not have to grow faster. Your looking at growth of the population as a whole, not the single cells

Goodie said:
What do you mean?

Basically that for cells in suspension it does matter if you split them at mid log because they will keep growing but for cells that grow attached to the plate it doesn't matter at which stage you split them because they will arrest anyway due to the trypsin treatment. (your original question was: Should I always split my cells at their mid log phase?)

Goodie said:
For example why one splits a flask into two new flasks (split ratio 1/2) instead of 4 new flasks (1/4) ? Is that the amount of cells one needs that also decide it? :rolleyes:
Thanks.

Not just that, some cells need to be in close contact with their neighbours to be able to grow, they depend on growthfactors of surrounding cells that are released in the medium. If you dilute them too much they will just stop.
 

FAQ: What is the Best Time to Split Cells?

What is transfection and how does it work?

Transfection is a laboratory technique used to introduce foreign molecules, such as DNA or RNA, into cells. This is typically done using a chemical, electrical, or viral method. Once the foreign molecules are inside the cells, they can carry out their intended function and potentially alter the behavior of the cells.

What is the purpose of performing tissue culture?

Tissue culture is a method used to grow and maintain cells or tissues in a controlled environment. This is often done to study the behavior of cells, test the effects of different drugs or treatments, or to produce large quantities of cells for research or medical purposes.

What are some common techniques for transfection?

There are several techniques for transfection, including chemical methods such as lipofection and calcium phosphate co-precipitation, electrical methods such as electroporation, and viral methods such as retroviral or adenoviral vectors. The choice of technique depends on the type of cells and the desired outcome.

How do you optimize transfection efficiency?

Transfection efficiency refers to the percentage of cells that successfully take up the foreign molecules. To optimize transfection efficiency, factors such as the type of transfection reagent, the concentration of DNA or RNA, and the health of the cells should be carefully considered and optimized. Additionally, using a reporter gene or fluorescent marker can help assess transfection efficiency and make adjustments as needed.

What are the potential challenges of transfection-tissue culture experiments?

One of the main challenges of transfection-tissue culture experiments is the variability in transfection efficiency between different cell types and even within the same type of cells. This can make it difficult to compare results between experiments. Additionally, transfection can also cause stress or damage to the cells, leading to changes in their behavior or function. Proper controls and careful optimization can help address these challenges.

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