Correction: Rapid fabrication of functionalised poly(dimethylsiloxane) microwells for cell aggregate formation.

Correction for 'Rapid fabrication of functionalised poly(dimethylsiloxane) microwells for cell aggregate formation' by A. Forget et al., Biomater. Sci., 2017, 5, 828-836.

Rapid fabrication of functionalised poly(dimethylsiloxane) microwells for cell aggregate formation.

Cell aggregates reproduce many features of the natural architecture of functional tissues, and have therefore become an important in vitro model of tissue function. In this study, we present an efficient and rapid method for the fabrication of site specific functionalised poly(dimethylsiloxane) (PDMS) microwell arrays that promote the formation of insulin-producing beta cell (MIN6) aggregates. Microwells were prepared using an ice templating technique whereby aqueous droplets were frozen on a surface and PDMS was cast on top to form a replica. By employing an aqueous alkali hydroxide solution, we demonstrate exclusive etching and functionalisation of the microwell inner surface, thereby allowing the selective absorption of biological factors within the microwells. Additionally, by manipulating surface wettability of the substrate through plasma polymer coating, the shape and profile of the microwells could be tailored. Microwells coated with antifouling Pluronic 123, bovine serum albumin, collagen type IV or insulin growth factor 2 were employed to investigate the formation and stability of MIN6 aggregates in microwells of different shapes. MIN6 aggregates formed with this technique retained insulin expression. These results demonstrate the potential of this platform for the rapid screening of biological factors influencing the formation and response of insulin-producing cell aggregates without the need for expensive micromachining techniques.

IGF-2 coated porous collagen microwells for the culture of pancreatic islets.

Islet transplantation, the only curative therapy for type I diabetes, requires isolation of the graft in highly specialized facilities for its later dispatch to remote transplantation centres. During transport and culture, many valuable cells are lost due to several factors such as mechanical stress, islet aggregation and dissociation. Here, we evaluate a porous microwell array sheet made of natural collagen type I extracellular matrix (ECM) protein as a novel islet culture substrate. This culture platform can be coated with IGF-2, a growth factor favorable for islet survival, and allows segregation of the islets within the porous microwell sheet, preventing aggregation. This design shows promising results for improving human pancreatic islets viability and function during culture and could form a novel paradigm for the transport of islets between isolation and transplantation centres.

Antibacterial properties of nitric oxide-releasing porous silicon nanoparticles.

In this study, the antibacterial efficacy of NO-releasing porous silicon nanoparticles (pSiNPs) is reported. NO-releasing pSiNPs were produced via the conjugation of S-nitrosothiol (SNO) and S-nitrosoglutathione (GSNO) donors to the nanoparticle surfaces. The release of the conjugated NO caused by the decomposition of the conjugated SNO and GSNO was boosted in the presence of ascorbic acid. The released NO was bactericidal to Gram-positive (Staphylococcus aureus) and Gram-negative bacteria (Escherichia coli), and eliminated bacterial growth within 2 h of incubation without compromising the viability of mammalian cells. These results demonstrate the advantages of NO-releasing pSiNPs for antibacterial applications, for example, in chronic wound treatment.

Small interfering RNA delivery by polyethylenimine-functionalised porous silicon nanoparticles.

In this study, thermally hydrocarbonised porous silicon nanoparticles (THCpSiNPs) capped with polyethylenimine (PEI) were fabricated, and their potential for small interfering RNA (siRNA) delivery was investigated in an in vitro glioblastoma model. PEI coating following siRNA loading enhanced the sustained release of siRNA, and suppressed burst release effects. The positively-charged surface improved the internalisation of the nanoparticles across the cell membrane. THCpSiNP-mediated siRNA delivery reduced mRNA expression of the MRP1 gene, linked to the resistence of glioblastoma to chemotherapy, by 63% and reduced MRP1-protein levels by 70%. MRP1 siRNA loaded nanoparticles did not induce cytotoxicity in glioblastoma cells, but markedly reduced cell proliferation. In summary, the results demonstrated that non-cytotoxic cationic THCpSiNPs are promising vehicles for therapeutic siRNA delivery.

Method for the generation and cultivation of functional three-dimensional mammary constructs without exogenous extracellular matrix.

During puberty, pregnancy, lactation and post-lactation, breast tissue undergoes extensive remodelling and the disruption of these events can lead to cancer. In vitro studies of mammary tissue and its malignant transformation regularly employ mammary epithelial cells cultivated on matrigel or floating collagen rafts. In these cultures, mammary epithelial cells assemble into three-dimensional structures resembling in vivo acini. We present a novel technique for generating functional mammary constructs without the use of matrix substitutes.