Final Report Abstract

Cells are surrounded by a network of protein nanofibers that forms the extracellular matrix. When an injury occurs, a nanofibrous fibrin clot initially closes the wound to initiate tissue repair. Since there is a great need for new fibrous protein scaffolds with tailored functionality, we have developed different techniques to fabricate nanofibrous protein scaffolds under physiological in vitro conditions. Our key methods involve template-assisted extrusion and self-assembly of fibrinogen and collagen. These techniques enabled us to tailor the molecular composition, nanotopography and hierarchical arrangement of the resulting fibrous constructs. To study topography-related changes of cell growth, we introduced a new patterning process to prepare collagen and fibrinogen scaffolds with nanofibrous and planar topography in selected regions. Cell studies revealed that these topography variations induced changes in the fibroblast size, morphology and migration. When collagen nanofibers were used as modification on alumina nanopores, they improved fibroblast and keratinocyte adhesion and prevented penetration of E. Coli bacteria. When microporous alumina textiles were modified with collagen nanofibers, we observed a roll-up effect that resulted in free-standing collagen scaffolds that could become interesting for skin tissue engineering. With salt-induced self-assembly we introduced a novel routine to prepare fibrinogen nanofibers in vitro. Fiber assembly was accompanied by minor conformational changes, and the mechanical characteristics of self-assembled fibrinogen scaffolds were close to the range of native fibrin. Fibrinogen nanofibers were highly biocompatible with fibroblasts, keratinocytes and blood platelets, and no E. Coli bacteria could penetrate through the nanofibers. Depending on the substrate material, our process offered the unique ability to produce free-standing or immobilized fiber matrices. By upscaling the self-assembly process, nanofibrous fibrinogen scaffolds with dimensions in the centimeter range could be fabricated. These new fiber preparation methods have provided us with a versatile toolbox to study selected aspects of cell-material interactions in vitro and to develop new materials for regenerative medicine.

Publications

• Nanopore Diameters Tune Strain in Extruded Fibronectin Fibers. Nano Letters, 15(10), 6357-6364.
  Raoufi, Mohammad; Das, Tamal; Schoen, Ingmar; Vogel, Viola; Brüggemann, Dorothea & Spatz, Joachim P.
  
• Template-assisted extrusion of biopolymer nanofibers under physiological conditions. Integrative Biology, 8(10), 1059-1066.
  Raoufi, Mohammad; Aslankoohi, Neda; Mollenhauer, Christine; Boehm, Heike; Spatz, Joachim P. & Brüggemann, Dorothea
  
• Controlling the Multiscale Structure of Nanofibrous Fibrinogen Scaffolds for Wound Healing. Nano Letters, 19(9), 6554-6563.
  Stapelfeldt, Karsten; Stamboroski, Stephani; Walter, Irina; Suter, Naiana; Kowalik, Thomas; Michaelis, Monika & Brüggemann, Dorothea
  
• Fabrication of 3D-nanofibrous fibrinogen scaffolds using salt-induced self assembly. Biofabrication, 11(2), 025010.
  Stapelfeldt, Karsten; Stamboroski, Stephani; Mednikova, Polina & Brüggemann, Dorothea
  
• Phosphorylation of Fibronectin Influences the Structural Stability of the Predicted Interchain Domain. Journal of Chemical Information and Modeling, 59(10), 4383-4392.
  Kulke, Martin; Uhrhan, Myriam; Geist, Norman; Brüggemann, Dorothea; Ohler, Bastian; Langel, Walter & Köppen, Susan
  
• Verfahren zur Herstellung von Biomaterialien mit porösen und glatten Topographien und deren Verwendung, DE patent 10 2019 123 799.8, 2019
  Suter, N. & Brüggemann, D.
  
• Spatial patterning of nanofibrous collagen scaffolds modulates fibroblast morphology. Biofabrication, 13(1), 015007.
  Suter, Naiana; Stebel, Sophie; Rianna, Carmela; Radmacher, Manfred & Brüggemann, Dorothea
  
• Wet-spinning of magneto-responsive helical chitosan microfibers. Beilstein Journal of Nanotechnology, 11, 991-999.
  Brüggemann, Dorothea; Michel, Johanna; Suter, Naiana; Grande de Aguiar, Matheus & Maas, Michael
  
• Effect of Collagen Nanofibers and Silanization on the Interaction of HaCaT Keratinocytes and 3T3 Fibroblasts with Alumina Nanopores. ACS Applied Bio Materials, 4(2), 1852-1862.
  Dutta, Deepanjalee; Markhoff, Jana; Suter, Naiana; Rezwan, Kurosch & Brüggemann, Dorothea
  
• Effect of interface-active proteins on the salt crystal size in waterborne hybrid materials. Applied Adhesion Science, 9(1).
  Stamboroski, Stephani; Boateng, Kwasi; Leite, Cavalcanti Welchy; Noeske, Michael; Beber, Vinicius Carrillo; Thiel, Karsten; Grunwald, Ingo; Schiffels, Peter; Dieckhoff, Stefan & Brüggemann, Dorothea
  
• Influence of Divalent Metal Ions on the Precipitation of the Plasma Protein Fibrinogen. Biomacromolecules, 22(11), 4642-4658.
  Stamboroski, Stephani; Boateng, Kwasi; Lierath, Jana; Kowalik, Thomas; Thiel, Karsten; Köppen, Susan; Noeske, Paul-Ludwig Michael & Brüggemann, Dorothea
  
• Principles of Fibrinogen Fiber Assembly In Vitro. Macromolecular Bioscience, 21(5).
  Stamboroski, Stephani; Joshi, Arundhati; Noeske, Paul‐Ludwig Michael; Köppen, Susan & Brüggemann, Dorothea
  
• Self-assembled fibrinogen nanofibers support fibroblast adhesion and prevent E. coli infiltration. Materials Science and Engineering: C, 126, 112156.
  Suter, Naiana; Joshi, Arundhati; Wunsch, Timo; Graupner, Nina; Stapelfeldt, Karsten; Radmacher, Manfred; Müssig, Jörg & Brüggemann, Dorothea
  
• Nanofiber Topographies Enhance Platelet‐Fibrinogen Scaffold Interactions. Advanced Healthcare Materials, 11(14).
  Kenny, Martin; Stamboroski, Stephani; Taher, Reem; Brüggemann, Dorothea & Schoen, Ingmar
  
• Assembly of Rolled-Up Collagen Constructs on Porous Alumina Textiles. ACS Nanoscience Au, 3(4), 286-294.
  Dutta, Deepanjalee; Graupner, Nina; Müssig, Jörg & Brüggemann, Dorothea
  
• Self-Assembled Fibrinogen Scaffolds Support Cocultivation of Human Dermal Fibroblasts and HaCaT Keratinocytes. ACS Omega, 8(9), 8650-8663.
  Joshi, Arundhati; Nuntapramote, Titinun & Brüggemann, Dorothea