Collagen–carbon nanotube composite materials as scaffolds in tissue engineering

MacDonald, Rebecca A.; Laurenzi, Brendan F.; Viswanathan, G.; Ajayan, Pulickel M.; Stegemann, Jan P.

doi:10.1002/jbm.a.30386

Cited by 356 publications

(249 citation statements)

References 33 publications

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“…For instance, MacDonald et al [43], using aortic smooth muscle cells, showed that constructs containing 2 wt% CNTs in a 2 mg/mL collagen gel exhibited delayed gel compaction compared to that observed with lower concentrations of CNTs and to the control (absence of CNTs). Importantly, they also determined that the cell viability was consistently above 85% in all the constructs.…”

Section: Resultsmentioning

confidence: 99%

“…When collagen fibrillogenesis is initiated, CNTs may become incorporated into the triple-helical collagen molecule, or may remain as a separate phase linking the collagen fi bers. It is likely that the carboxyl and hydroxyl groups present on the surface of CNTs can form covalent and hydrogen bonds with amino groups extending from the collagen chains [41,43]. However, further theoretical and experimental work still needs to be performed to clarify these assumptions.…”

Section: Resultsmentioning

confidence: 99%

“…MacDonald et al showed that the presence of carboxylated CNTs in collagen/SWCNT composites did not alter the initial formation of gels containing live smooth muscle cells, nor affect the cell viability or proliferation of these cells. However, they noted that matrices containing 2 wt% SWCNTs showed a delay in gel compaction during the first three days of the experiment, indicating that CNTs improve the mechanical strength of the biocomposite gel [43]. In recent work, MacDonald et al used collagen/CNT biocomposites to show that this product can be used as a substrate to study electrical stimulation of cells and can act as a transducer for future biosensors [44,45].…”

Section: Introductionmentioning

confidence: 99%

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Nanostructured 3-D collagen/nanotube biocomposites for future bone regeneration scaffolds

et al. 2009

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The fi eld of bionanotechnology has been rapidly growing during the last few years and we can now envision a controllable integration between biological and artificial matter, where new biomimetic structures with a wide range of chemical and physical properties will promote the development of a novel generation of medical devices. In this work we describe a collagen/carbon nanotube composite which has the potential to be used as a scaffold for tissue regeneration. Because this biocomposite incorporates the advantageous properties of both collagen and carbon nanotubes, it has most of the characteristics that an ideal biomaterial requires in order to be used as an osteoinductive agent. This biocomposite is bioresorbable and biodegradable and has the desired mechanical rigidity while maintaining a three-dimensional(3-D) nanostructured surface. Tuned stability and swelling were achieved under fluid environments by varying the amount of carbon nanotubes (CNTs) incorporated into the composite. These variations can dictate the degree of interaction between fibroblastic cells and the biomaterials. Proof-of-concept was shown by performing an in vitro induced mineralization of hydroxylapatite crystals under physiological conditions. Furthermore, the ability to attach biofunctional groups to the CNT walls can open a new road for tissue regeneration since the combination of CNTs with specific growth factors or cellular ligands can create an environment capable of signaling and infl uencing specifi c cell functions. Our observations suggest that collagen/carbon nanotube biocomposites will have important uses in a wide range of biotechnological areas.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Nanostructured 3-D collagen/nanotube biocomposites for future bone regeneration scaffolds

et al. 2009

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“…Isolated collagen monomers can re-assemble in vitro to form fibrils that resemble those in living tissue, with a characteristic 67 nm periodic structure called a D-period. [3,4] There is much interest in carbon nanotubes as a reinforcement additive for tissue engineering materials such as collagen gels, and cartilagenous simulants, [5][6][7][8][9]. In the present work, results are presented showing the in-vitro fibril formation of pepsin treated collagen in the presence of carbon nanotubes coated with polystyrene/polyanaline side chains, which resemble, somewhat, proteoglycan macromolecules, [10].…”

Section: Introductionmentioning

confidence: 83%

Collagen gel formation in the presence of a carbon nanobrush

Dombi

Purohit

Martin

et al. 2015

J Mater Sci: Mater Med

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Type I, bovine skin collagen was allowed to gel in the presence of various concentrations of a carbon nanotube material covered with a polystyrene/polyaniline copolymer, called a carbon nanobrush, CNB. The rate of collagen gelation was enhanced by the presence of the CNB in a dose dependent manner. The extent of collagen gelation was due to the concentration of collagen and not the amount of CNB. Collagen D-periodicity, and average fibril diameter were unchanged by the CNB material as seen in transmission electron micrographs. Gel tensile strength was reduced by the presence of the the CNB in a dose related manner. The collagen-CNB mixture may have a role in the repair and reconstruction of wounds or degenerated connective tissue.

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“…In vitro work has shown that several different cells types have been successfully grown on CNT/biopolymer composites. MacDonald found t h a t b l e n d s o f S W N T w i t h c o l l a g e n support smooth muscle cell growth (MacDonald, et al 2005). L929 mouse fibroblasts have been successfully grown on CNT scaffolds (Correa-Duarte, et al 2004) Abarrategi et al demonstrates the use of scaffolds composed of a major fraction of MWCNT (up to 89wt%) and a minor one of chitosan, and with a well-defined microchannel porous structure as biocompatible and biodegradable supports for culture growth.…”

Section: Biopolymer/cnt Composite As Tissue Scaffoldsmentioning

confidence: 99%