Results 261 to 270 of about 386,409 (314)

Zinc- and fluoride-containing bioactive glass enhances angiogenesis-mediated bone regeneration via M2d macrophage activation. [PDF]

Sci Rep
Otake K, Kondo T, Kakinuma H, Sato Y, Ambo S, Ashry A, Engkatanachai K, Sato J, Egusa H.   +8 more
europepmc   +1 more source

Bioinspired Engineering of Streamlined Skeletal Interoception: Neural Bioprinted Piezoelectric Scaffolds for Neuro-Vascularized Bone Regeneration. [PDF]

Adv Sci (Weinh)
Su Y, Wang H, Liu W, Chen K, Min Y, Zhu J, Li X, Su A, Yang H, Yang L, Ji Y, Zhang Y, Zheng J, Yang C, He C, Li T, Chen S, Wu T, Chen X.   +18 more
europepmc   +1 more source

"Triangular ostectomy": effective removal of bony interference during orthognathic surgery for better postoperative bone regeneration. [PDF]

Front Oral Health
Wu H, Wei H, Long Q, Cao J, Sun H.
europepmc   +1 more source

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Bone Regeneration and Repair

Current Stem Cell Research & Therapy, 2010
In the face of mounting clinical demand, and armed with reconstructive techniques that are technically challenging and frequently result in suboptimal patient outcomes, increasing focus is being placed on tissue engineering and regenerative medicine as a potential source of novel skeletal reconstructive approaches.
Nicholas J, Panetta, Deepak M, Gupta, Michael T, Longaker   +2 more
openaire   +2 more sources

Cannabinoids and bone regeneration

Drug Metabolism Reviews, 2019
Bone is a complex tissue with unique properties such as high strength and regeneration capabilities while carrying out multiple functions. Bone regeneration occurs both in physiological situations (bone turnover) and in pathological situations (e.g. fractures), being performed by osteoblasts and osteoclasts.
Dragos, Apostu, Ondine, Lucaciu, Alexandru, Mester, Horea, Benea, Daniel, Oltean-Dan, Florin, Onisor, Mihaela, Baciut, Simion, Bran   +7 more
openaire   +2 more sources

Tissue-engineered bone regeneration

Nature Biotechnology, 2000
Bone lesions above a critical size become scarred rather than regenerated, leading to nonunion. We have attempted to obtain a greater degree of regeneration by using a resorbable scaffold with regeneration-competent cells to recreate an embryonic environment in injured adult tissues, and thus improve clinical outcome.
H, Petite, V, Viateau, W, Bensaïd, A, Meunier, C, de Pollak, M, Bourguignon, K, Oudina, L, Sedel, G, Guillemin   +8 more
openaire   +2 more sources

Orthotopic bone implants for bone regeneration

Stomatologiya, 2017
Biotechnology industry is rapidly developing. The elaboration of new biomaterials for bone reconstruction is one of the most perspective directions in tissue engineering. There are millions of surgical operations associated with use of bone graft materials every year.
A A, Muraev, S Yu, Ivanov, S G, Ivashkevich, V N, Gorshenev, A T, Teleshev, A V, Kibardin, K K, Kobets, V K, Dubrovin   +7 more
openaire   +2 more sources

Nanomaterial-based bone regeneration

Nanoscale, 2017
Bone diseases/injuries have been driving an urgent quest for bone substitutes for bone regeneration. Nanoscaled materials with bone-mimicking characteristics may create suitable microenvironments to guide effective bone regeneration. In this review, the natural hierarchical architecture of bone and its regeneration mechanisms are elucidated.
Yulin Li, Changsheng Liu
openaire   +2 more sources

Osteomacs and Bone Regeneration

Current Osteoporosis Reports, 2017
Mounting evidence supporting the critical contribution of macrophages, in particular osteal macrophages, to bone regeneration is reviewed. We specifically examine the potential role of macrophages in the basic multicellular units coordinating lifelong bone regeneration via remodelling and bone regeneration in response to injury.
Batoon, Lena, Millard, Susan Marie, Raggatt, Liza Jane, Pettit, Allison Robyn   +3 more
openaire   +3 more sources