Electrospun nanodiamond-silk fibroin membranes: a multifunctional platform for biosensing and wound healing applications

TL;DR

This study develops nanodiamond-silk fibroin membranes that enable noninvasive temperature sensing and promote wound healing, demonstrating biocompatibility, antibacterial properties, and effective temperature monitoring in vitro and in vivo.

Contribution

The paper introduces a novel electrospun nanodiamond-silk membrane platform with integrated temperature sensing and antibacterial features for advanced wound care.

Findings

Membranes support wound healing and are biocompatible.

Nanodiamonds improve thermal stability and enable temperature sensing.

Membranes exhibit antibacterial activity against Gram-negative bacteria.

Abstract

Next generation wound care technology capable of diagnosing wound parameters, promoting healthy cell growth and reducing pathogenic infections noninvasively will provide patients with an improved standard of care and an accelerated wound repair. Temperature is one of the indicating biomarkers specific to chronic wounds. This work reports a hybrid, multifunctional optical platform: nanodiamond-silk membranes as bioinspired dressings capable of temperature sensing and wound healing. The hybrid was fabricated through electrospinning and formed sub-micron fibrous membranes with high porosity. The silk fibres are capable of compensating for the lack of extracellular matrix at the wound site, supporting the wound healing. The negatively charged nitrogen vacancy (NV-) color centres in nanodiamonds (NDs) exhibit optically detected magnetic resonance (ODMR) properties and act as fluorescent nanoscale thermometers, capable of sensing temperature variations associated to the presence of infection or inflammation in a wound, without physically removing the dressing. Our results show that the presence of NDs in the hybrid ND-silk membranes improve the thermal stability of silk fibres. The NV- color centres in NDs embedded in silk fibres exhibit well-retained fluorescent and ODMR. Using the NV- centres as fluorescent nanoscale thermometers, we achieved temperature sensing at a range of temperatures, including the biologically relevant temperature window, on cell-cultured ND-silk membranes. Enhancement in the temperature sensitivity of the NV- centres was observed for the hybrids. The membranes were further tested in vivo in a murine wound healing model and demonstrated biocompatibility and equivalent wound closure rates as the control wounds. Additionally, the hybrid ND-silk membranes showed selective antifouling and biocidal propensity toward Gram-negative Pseudomonas aeruginosa and Escherichia coli.