Dergi makalesi Açık Erişim
Eren, E. Deniz; Tansik, Gulistan; Tekinay, Ayse B.; Guler, Mustafa O.
<?xml version='1.0' encoding='UTF-8'?> <record xmlns="http://www.loc.gov/MARC21/slim"> <leader>00000nam##2200000uu#4500</leader> <datafield tag="700" ind1=" " ind2=" "> <subfield code="a">Tansik, Gulistan</subfield> <subfield code="u">Bilkent Univ, Inst Mat Sci & Nanotechnol, Natl Nanotechnol Res Ctr UNAM, TR-06800 Ankara, Turkey</subfield> </datafield> <datafield tag="700" ind1=" " ind2=" "> <subfield code="a">Tekinay, Ayse B.</subfield> <subfield code="u">Bilkent Univ, Inst Mat Sci & Nanotechnol, Natl Nanotechnol Res Ctr UNAM, TR-06800 Ankara, Turkey</subfield> </datafield> <datafield tag="700" ind1=" " ind2=" "> <subfield code="a">Guler, Mustafa O.</subfield> <subfield code="u">Univ Chicago, Inst Mol Engn, Chicago, IL 60637 USA</subfield> </datafield> <datafield tag="909" ind1="C" ind2="4"> <subfield code="p">CHEMNANOMAT</subfield> <subfield code="v">4</subfield> <subfield code="n">8</subfield> <subfield code="c">837-845</subfield> </datafield> <datafield tag="980" ind1=" " ind2=" "> <subfield code="a">user-tubitak-destekli-proje-yayinlari</subfield> </datafield> <datafield tag="540" ind1=" " ind2=" "> <subfield code="a">Creative Commons Attribution</subfield> <subfield code="u">http://www.opendefinition.org/licenses/cc-by</subfield> </datafield> <datafield tag="024" ind1=" " ind2=" "> <subfield code="a">10.1002/cnma.201700354</subfield> <subfield code="2">doi</subfield> </datafield> <datafield tag="245" ind1=" " ind2=" "> <subfield code="a">Mineralized Peptide Nanofiber Gels for Enhanced Osteogenic Differentiation</subfield> </datafield> <datafield tag="100" ind1=" " ind2=" "> <subfield code="a">Eren, E. Deniz</subfield> </datafield> <datafield tag="909" ind1="C" ind2="O"> <subfield code="o">oai:zenodo.org:33845</subfield> <subfield code="p">user-tubitak-destekli-proje-yayinlari</subfield> </datafield> <datafield tag="650" ind1="1" ind2="7"> <subfield code="2">opendefinition.org</subfield> <subfield code="a">cc-by</subfield> </datafield> <datafield tag="260" ind1=" " ind2=" "> <subfield code="c">2018-01-01</subfield> </datafield> <datafield tag="856" ind1="4" ind2=" "> <subfield code="u">https://aperta.ulakbim.gov.trrecord/33845/files/bib-bcb7913a-64b2-4364-ad62-0e3fdb86507d.txt</subfield> <subfield code="z">md5:7cc9baee6b72a59eed674de7a0b25ba7</subfield> <subfield code="s">157</subfield> </datafield> <datafield tag="542" ind1=" " ind2=" "> <subfield code="l">open</subfield> </datafield> <controlfield tag="005">20210315190101.0</controlfield> <controlfield tag="001">33845</controlfield> <datafield tag="980" ind1=" " ind2=" "> <subfield code="a">publication</subfield> <subfield code="b">article</subfield> </datafield> <datafield tag="520" ind1=" " ind2=" "> <subfield code="a">Mineral deposition is observed in both bacterial and eukaryotic organisms through a broad range of mechanisms. Both organic and inorganic components play crucial roles in the formation of mineralized tissues, and acidic proteins are particularly important in this context owing to their ability to stimulate nucleation of minerals. Here, we present negatively-charged self-assembling peptide amphiphile molecules as a template to nucleate calcium phosphate mineralization in a bioactive scaffold environment. Acidic peptide molecules were shown to induce formation of hydroxyapatite like calcium phosphate mineralization, which was characterized by scanning electron microscopy, transmission electron microscopy, thermogravimetric analysis, X-ray diffractometry, oscillatory rheology and atomic force microscopy. The osteoblast-like cells were found to reveal enhanced osteogenic differentiation on pre-mineralized peptide nanofiber networks, suggesting that mineral deposition can be used as a means of enhancing the bioactivity of peptide-based scaffold systems.</subfield> </datafield> </record>
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