Are super hydrophilic surfaces suitable for cell attachment?
Best insight from top research papers
Super hydrophilic surfaces have been found to have varying effects on cell attachment. Some studies have shown that super hydrophilic surfaces can improve cell adhesion, proliferation, and differentiation capacity . However, other studies have found that higher hydrophilicity can actually decrease cell attachment . It is important to note that the specific properties of the super hydrophilic surface, such as the material used and the method of preparation, can influence its suitability for cell attachment. For example, a super hydrophilic cell growth surface prepared using a plasma etching treatment and acrylic monomer grafting has been shown to have a lasting stable super hydrophilic effect and meet the biological property requirements for cell culture . Overall, further research is needed to fully understand the relationship between super hydrophilic surfaces and cell attachment.
Answers from top 5 papers
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| Papers (5) | Insight |
|---|---|
| The paper does not specifically mention "super hydrophilic surfaces." The paper discusses the effects of hydrophilicity on cell attachment, but does not mention super hydrophilic surfaces. | |
| The paper does not directly mention "super hydrophilic surfaces." The paper discusses the manufacturing of implants with a hydrophilic surface, which provides superior osseointegration or cell attachment properties. | |
| The paper does not directly mention "super hydrophilic surfaces." The paper discusses a method for manufacturing implants with improved hydrophilic properties, but it does not specifically address whether super hydrophilic surfaces are suitable for cell attachment. | |
| The paper states that the super-hydrophilic cell growth surface formed using the described method is suitable for cell culture, indicating that it is suitable for cell attachment. | |
| The paper states that the high potential super-hydrophilic polypeptide monolayer film can improve cell adhesion, proliferation, and differentiation capacity, suggesting that super hydrophilic surfaces are suitable for cell attachment. |
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