A new method using insert-based systems (IBS) to improve cell behavior study on flexible and rigid biomaterials

Abstract: In vitro studies about biomaterials biological properties are essential screening tests. Yet cell cultures encounter difficulties related to cell retention on material surface or to the observation of both faces of permeable materials. The objective of the present study was to develop a reliable in vitro method to study cell behavior on rigid and flexible/permeable biomaterials elaborating two specific insert-based systems (IBS-R and IBS-F respectively). IBS-R was designed as a specific cylindrical polytetrafl… Show more

“…Although cell loading was low, the use of a PTFE insert allowed optimal cell seeding and attachment on the scaffolds by preventing cell loss at the bottom of the culture well without affecting cell behavior (Grenade et al, 2016). Although cell loading was low, the use of a PTFE insert allowed optimal cell seeding and attachment on the scaffolds by preventing cell loss at the bottom of the culture well without affecting cell behavior (Grenade et al, 2016).…”

“…Both biomaterials induced similar cell behavior as the number of cells per pellet, cell coverage, and viability were comparable after 3 days of culture. Although cell loading was low, the use of a PTFE insert allowed optimal cell seeding and attachment on the scaffolds by preventing cell loss at the bottom of the culture well without affecting cell behavior (Grenade et al, 2016). The human tumor cell line MG-63 was employed in this study given their osteoblastic features like alkaline phosphatase activity and osteoblast-like markers as well as their use in dental biomaterial biocompatibility experimentation (Aisa et al, 1996;Bächle & Kohal, 2004;Boyan, Schwartz, Bonewald, & Swain, 1989;Clover & Gowen, 1994;Czuba, Quintana, De Pauw-Gillet, et al, 2018;Wu et al, 2014).…”

“…Arrow, periosteum. B, cranial bone; CaP, calciumphosphate; P, HA-TCP pellet; PTFE, polytetrafluoroethylene; S, skin proliferation at the periphery of the pellet as previously described (Grenade et al, 2016) (Figure 1b).…”

“…Each experiment was performed in triplicate ( n = 3) for each group and repeated three times. Pellets were maintained during culture by a polytetrafluoroethylene (PTFE) insert in order to inhibit cell proliferation at the periphery of the pellet as previously described (Grenade et al, ) (Figure b).…”

In vitro and in vivo biocompatibility of calcium‐phosphate scaffolds three‐dimensional printed by stereolithography for bone regeneration

“…Although cell loading was low, the use of a PTFE insert allowed optimal cell seeding and attachment on the scaffolds by preventing cell loss at the bottom of the culture well without affecting cell behavior (Grenade et al, 2016). Although cell loading was low, the use of a PTFE insert allowed optimal cell seeding and attachment on the scaffolds by preventing cell loss at the bottom of the culture well without affecting cell behavior (Grenade et al, 2016).…”

“…Both biomaterials induced similar cell behavior as the number of cells per pellet, cell coverage, and viability were comparable after 3 days of culture. Although cell loading was low, the use of a PTFE insert allowed optimal cell seeding and attachment on the scaffolds by preventing cell loss at the bottom of the culture well without affecting cell behavior (Grenade et al, 2016). The human tumor cell line MG-63 was employed in this study given their osteoblastic features like alkaline phosphatase activity and osteoblast-like markers as well as their use in dental biomaterial biocompatibility experimentation (Aisa et al, 1996;Bächle & Kohal, 2004;Boyan, Schwartz, Bonewald, & Swain, 1989;Clover & Gowen, 1994;Czuba, Quintana, De Pauw-Gillet, et al, 2018;Wu et al, 2014).…”

“…Arrow, periosteum. B, cranial bone; CaP, calciumphosphate; P, HA-TCP pellet; PTFE, polytetrafluoroethylene; S, skin proliferation at the periphery of the pellet as previously described (Grenade et al, 2016) (Figure 1b).…”

“…Each experiment was performed in triplicate ( n = 3) for each group and repeated three times. Pellets were maintained during culture by a polytetrafluoroethylene (PTFE) insert in order to inhibit cell proliferation at the periphery of the pellet as previously described (Grenade et al, ) (Figure b).…”

In vitro and in vivo biocompatibility of calcium‐phosphate scaffolds three‐dimensional printed by stereolithography for bone regeneration

Biocompatibility of polymer-infiltrated-ceramic-network (PICN) materials with Human Gingival Fibroblasts (HGFs)

Biocompatibility of polymer-infiltrated-ceramic-network (PICN) materials with Human Gingival Keratinocytes (HGKs)