1. Platelet Adhesion on Commercially Pure Titanium Plates in Vitro II. Immunofluorescence Visualization of PDGF-B, TGFβ1, and PPARγ Released from Activated Adherent Platelets
- Author
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Kazushige Isobe, Tomoyuki Kawase, Kazuhiro Okuda, Taisuke Watanabe, Akira Takahashi, Yutaka Kitamura, Tetsuhiro Tsujino, and Koh Nakata
- Subjects
Immunofluorescence ,Fibrin ,Article ,03 medical and health sciences ,0302 clinical medicine ,medicine ,Platelet ,titanium ,transforming growth factor β ,General Dentistry ,030304 developmental biology ,0303 health sciences ,peroxisome proliferator-activated receptor γ ,biology ,medicine.diagnostic_test ,Chemistry ,Regeneration (biology) ,platelet-derived growth factors ,platelet-rich plasma ,030206 dentistry ,Adhesion ,In vitro ,lcsh:RK1-715 ,adhesion ,lcsh:Dentistry ,Platelet-rich plasma ,biology.protein ,Biophysics ,Surface modification - Abstract
Recent progress in the industrial development of dental implants has improved their surface bio-affinity, while clinical implantologists attempt to improve it through coating with various compounds, including platelet-rich plasma (PRP) in clinical settings. However, it is poorly understood how PRP acts on titanium surfaces. To validate this surface modification method and demonstrate how platelet-derived soluble biomolecules released from the activated adherent platelets act on plain, commercially pure-titanium (cp-Ti) plates, we evaluated the distribution of biomolecules by immunofluorescence. PPAR&gamma, PDGF-B, and TGF&beta, 1 were similarly released at immunofluorescence levels from activated adherent platelets, retained in the surrounding extra-platelet spaces for a while, and did not immediately diffuse away to distant spaces. Exogenously added CaCl2 augmented release and retention of those biomolecules along with activation and aggregation. Taken together with our previous data regarding platelet adhesion, these findings suggest that especially when treated with CaCl2, platelets immediately adhere on cp-Ti plates to release their stored biomolecules in the absence of plasma proteins and that these biomolecules do not diffuse away, but stay longer in extra-platelet spaces around the platelets by newly formed, immature fibrin fiber fragments. Consequently, these retained biomolecules are anticipated to cooperatively stabilize implants by stimulating alveolar bone regeneration and integration.
- Published
- 2019