We are using cookies to implement functions like login, shopping cart or language selection for this website. Furthermore we use Google Analytics to create anonymized statistical reports of the usage which creates Cookies too. You will find more information in our privacy policy.
OK, I agree I do not want Google Analytics-Cookies
The International Journal of Oral & Maxillofacial Implants



Forgotten password?


Int J Oral Maxillofac Implants 28 (2013), No. 5     24. Oct. 2013
Int J Oral Maxillofac Implants 28 (2013), No. 5  (24.10.2013)

Page 1226-1231, doi:10.11607/jomi.3099, PubMed:24066312

Effects of Oral Implant Surface Roughness on Bacterial Biofilm Formation and Treatment Efficacy
Lin, Hai Yan / Liu, Yuelian / Wismeijer, Daniel / Crielaard, Wim / Deng, Dong Mei
Purpose: The aim of this study was to investigate the influence of oral implant surface roughness on bacterial biofilm formation and antimicrobial treatment efficacy.
Materials and Methods: Titanium disks with low-roughness pickled surfaces and with moderately rough sandblasted, acid-etched surfaces were used as substrata. Streptococcus mutans biofilms (1 and 3 days old) and Porphyromonas gingivalis biofilms (3 days old) were grown on the two types of substrata and then treated with 0.2% chlorhexidine. Biofilm viability was evaluated by a resazurin metabolism assay and by sonication-colony-forming unit counts.
Results: Surface roughness had no influence on the amount of biofilm formation by S mutans or P gingivalis in this in vitro biofilm model. However, it strongly affected the treatment efficacy of chlorhexidine on the biofilms formed by both species. Higher roughness resulted in lower efficacy. Furthermore, treatment efficacy was significantly reduced in older biofilms.
Conclusion: A moderately roughened surface did not enhance biofilm formation but reduced treatment efficacy of the biofilms. This finding indicates that efforts should be directed toward optimizing implant surface properties for effective antimicrobial treatment without compromising osseointegration.