Cell culturing is hard work. Because it's a highly technical process, there's a lot that can go wrong when you take cells from one source and manipulate them in another, from contamination to lackluster growth.
But there's also a lot that can go right. Over the past 100-plus years, adherent cell culture experiments have contributed to some of the most revolutionary advances in modern medicine, advancing our understanding of diseases like cancer and supporting the development of safe and effective therapeutics.
Fortunately, there's a lot more known about culturing now than when the in vitro pioneer, Ross Harrison, analyzed frog tissue on a glass slide in the early 1900s. In this guide, we share the basics learned from more than a century of tinkering with living cells, including how to seed, expand, and harvest cell cultures.
In buying cell culture lines, products come cryopreserved, which is necessary to maintain cell viability long-term. From that state, you'll need to thaw out and seed the cells, which shouldn't be rushed, even though it happens fast. And yet, this important step often does get hurried and sometimes overlooked, which risks contamination and doesn't give the cells the good, sterile start they need.
Here is the correct way to conduct the cell seeding process:
When it's time to scale up your cells, you'll need the right cell expansion approach. Cellular expansion is a necessary part of cell culture that relies on both efficiency and consistency. If you follow an inefficient workflow, you'll likely drive up the costs of supplies and labor. If you follow an inconsistent workflow, you could overstress your cells and kill them.
Striking the right balance will depend on your vessel choice. Multilayer options, such as the Corning® HYPERFlask®, can help life scientists establish friendly conditions for faster growth in a smaller space, and also with less labor and contamination risk.
Because not all vessels have the same growth area, researchers will typically think in terms of cells/cm2 yield when they are determining their vessel choice and the amount of associated reagents. They will then use this to consistently evolve their seed train into the amount of cells the researcher needs. For optimal growth, maintain the same ratio of cells/cm2 and mL/cm2 across vessels and reagents by doing the following:
You'll know cells are ready to harvest when they appear as a monolayer throughout the culture under the microscope. At that time, scientists will generally remove the cells via chemical or physical means.
Chemical removal via dissociation reagents needs to be optimized for the cell type and application in order to make sure cells are not negatively impacted by the reagent. By contrast, physical removal via cell scrapers may be best for strongly adherent, sensitive cells that might not tolerate dissociation reagents. Also consider your downstream application and how or whether the dissociation reagent may impact your studies.
If you choose to use dissociation reagents, follow this process aseptically using a pipette:
Now your cells are ready to count, so you can measure cell density and viability.
Adherent cell cultures can open your lab up to a whole new world of experimentation and downstream applications — and it can be fun too. But there can be a lot at stake when you're manipulating living cells, so it's important to do so correctly. By following these essential tips and working your way up to more advanced protocols, you can become a cell culture pro in no time.
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