Abstract
This study was inspired by the unique multi-scale and multi-level ‘brick-and-mortar’ (B&M) structure of nacre layers. We prepared the B&M, environmentally-friendly graphene oxide-carrageenan (GO-Car) nanocomposite films using the following steps. A natural polyhydroxy polymer, carrageenan, was absorbed on the surface of monolayer GO nanosheets through hydrogen-bond interactions. Following this, a GO-Car hybridized film was produced through a natural drying process. We conducted structural characterization in addition to analyzing mechanical properties and cytotoxicity of the films. Scanning electron microscope (SEM) and X-ray diffraction (XRD) analyses showed that the nanocomposite films had a similar morphology and structure to nacre. Furthermore, the results from Fourier transform infrared spectroscopy (FT-IR), Raman spectroscopy, X-ray photoelectron spectroscopy (XPS) and Thermogravimetric (TG/DTG) were used to explain the GO-Car interaction. Analysis from static mechanical testers showed that GO-Car had enhanced Young’s modulus, maximum tensile strength and breaking elongation compared to pure GO. The GO-Car nanocomposite films, containing 5% wt. of Car, was able to reach a tensile strength of 117 MPa. The biocompatibility was demonstrated using a RAW264.7 cell test, with no significant alteration found in cellular morphology and cytotoxicity. The preparation process for GO-Car films is simple and requires little time, with GO-Car films also having favorable biocompatibility and mechanical properties. These advantages make GO-Car nanocomposite films promising materials in replacing traditional petroleum-based plastics and tissue engineering-oriented support materials.
Highlights
Evolution over hundreds of millions of years has provided natural biomaterials with perfect structures and functions
We studied the morphology, structure, mechanical properties and cytotoxicity of graphite oxide (GO)-Car nanocomposite films
Cells adhered on the surface of nanocomposite films had clear outlines, with the oval shape being similar to the control group tissue culture polystyrene (TCPS). These results indicated that GO-Car nanocomposite films did not affect cellular morphology and cell proliferation
Summary
Evolution over hundreds of millions of years has provided natural biomaterials with perfect structures and functions. Among the numerous natural biomaterials, nacre has received widespread attention, due to its unique layered structure, high strength and outstanding toughness. The structural model of nacre has inspired people to prepare light, highly strong and ultra-tough layered nanocomposites [1,2,3,4]. The main components of natural nacre are aragonite-style calcium carbonate (about 95% wt.) and organic substrates (5% wt.). Organic substrates firmly hold the calcium carbonate sheets together, playing a role like cement. This structure can effectively disperse the pressure imposed on the shell, which is a very favorable mechanical property.
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