| Author | Gačanin, Jasmina | dc.contributor.author |
| Author | Hedrich, Jana | dc.contributor.author |
| Author | Sieste, Stefanie | dc.contributor.author |
| Author | Glasser, Gunnar | dc.contributor.author |
| Author | Lieberwirth, Ingo | dc.contributor.author |
| Author | Schilling, Corinna | dc.contributor.author |
| Author | Fischer, Stephan | dc.contributor.author |
| Author | Barth, Holger | dc.contributor.author |
| Author | Knöll, Bernd | dc.contributor.author |
| Author | Synatschke, Christopher V. | dc.contributor.author |
| Author | Weil, Tanja | dc.contributor.author |
| Date of accession | 2023-06-05T12:08:56Z | dc.date.accessioned |
| Available in OPARU since | 2023-06-05T12:08:56Z | dc.date.available |
| Date of first publication | 2018-11-09 | dc.date.issued |
| Abstract | The synthesis of hybrid hydrogels by pH-controlled structural transition with exceptional rheological properties as cellular matrix is reported. “Depsi” peptide sequences are grafted onto a polypeptide backbone that undergo a pH-induced intramolecular O–N–acyl migration at physiological conditions affording peptide nanofibers (PNFs) as supramolecular gelators. The polypeptide–PNF hydrogels are mechanically remarkably robust. They reveal exciting thixotropic behavior with immediate in situ recovery after exposure to various high strains over long periods and self-repair of defects by instantaneous reassembly. High cytocompatibility, convenient functionalization by coassembly, and controlled enzymatic degradation but stability in 2D and 3D cell culture as demonstrated by the encapsulation of primary human umbilical vein endothelial cells and neuronal cells open many attractive opportunities for 3D tissue engineering and other biomedical applications. | dc.description.abstract |
| Language | en | dc.language.iso |
| Publisher | Universität Ulm | dc.publisher |
| License | CC BY-NC 4.0 International | dc.rights |
| Link to license text | https://creativecommons.org/licenses/by-nc/4.0/ | dc.rights.uri |
| Keyword | cell cultivation | dc.subject |
| Keyword | depsi peptide | dc.subject |
| Keyword | hydrogels | dc.subject |
| Keyword | peptide nanofibers | dc.subject |
| Dewey Decimal Group | DDC 530 / Physics | dc.subject.ddc |
| Dewey Decimal Group | DDC 540 / Chemistry & allied sciences | dc.subject.ddc |
| Dewey Decimal Group | DDC 620 / Engineering & allied operations | dc.subject.ddc |
| LCSH | Cell culture | dc.subject.lcsh |
| LCSH | Colloids | dc.subject.lcsh |
| LCSH | Thixotropy | dc.subject.lcsh |
| Title | Autonomous ultrafast self-healing hydrogels by pH-responsive functional nanofiber gelators as cell matrices | dc.title |
| Resource type | Wissenschaftlicher Artikel | dc.type |
| Version | publishedVersion | dc.description.version |
| DOI | http://dx.doi.org/10.18725/OPARU-48926 | dc.identifier.doi |
| URN | http://nbn-resolving.de/urn:nbn:de:bsz:289-oparu-49002-5 | dc.identifier.urn |
| GND | Zellkultur | dc.subject.gnd |
| GND | Hydrogel | dc.subject.gnd |
| GND | Thixotropie | dc.subject.gnd |
| Faculty | Fakultät für Naturwissenschaften | uulm.affiliationGeneral |
| Faculty | Medizinische Fakultät | uulm.affiliationGeneral |
| Institution | Institut für Anorganische Chemie I (Materialien und Katalyse) | uulm.affiliationSpecific |
| Institution | UKU. Institut für Pharmakologie und Toxikologie | uulm.affiliationSpecific |
| Institution | Institut für Physiologische Chemie | uulm.affiliationSpecific |
| Peer review | ja | uulm.peerReview |
| DCMI Type | Text | uulm.typeDCMI |
| Category | Publikationen | uulm.category |
| DOI of original publication | 10.1002/adma.201805044 | dc.relation1.doi |
| Source - Title of source | Advanced Materials | source.title |
| Source - Place of publication | Wiley | source.publisher |
| Source - Volume | 31 | source.volume |
| Source - Issue | 2 | source.issue |
| Source - Year | 2019 | source.year |
| Source - Article number | 1805044 | source.articleNumber |
| Source - ISSN | 0935-9648 | source.identifier.issn |
| Source - eISSN | 1521-4095 | source.identifier.eissn |
| EU project uulm | AD-gut / Alzheimer Disease - gut connection / EC / H2020 / 686271 | uulm.projectEU |
| Community | Fakultät für Naturwissenschaften | uulm.community |
| Community | Medizinische Fakultät | uulm.community |
| Community | Universitätsklinikum Ulm | uulm.community |
| WoS | 000455111100016 | uulm.identifier.wos |
| Bibliography | uulm | uulm.bibliographie |
| Is Supplemented By | https://onlinelibrary.wiley.com/action/downloadSupplement?doi=10.1002%2Fadma.201805044&file=adma201805044-sup-0001-S1.pdf | dc.relation.isSupplementedBy |
| DFG project uulm | SFB 1149 Teilprojekt A04 / Zelltypspezifische Trägerproteine für die gezielte pharmakologische Hemmung der Rho-/Aktin-abhängigen Leukozyten-Rekrutierung in den Alveolarraum nach stumpfem Thoraxtrauma / DFG / 251293561 | uulm.projectDFG |
| DFG project uulm | Identification and functional characterization of novel nanofiber-growth factor hybrid molecules for regeneration in a mouse traumatic brain injury model / DFG / 441734479 [KN543/6] | uulm.projectDFG |
| Project uulm | Self-assembling peptides as potent cell-type specific enhancers of retroviral gene transfer (extension) / Volkswagenstiftung / 89943 | uulm.projectOther |
