Nanoscale & Nanoscale Advances Blog

The need for tough, easily producible, tissue adhesives for medical applications is significant, and much recent research has focused on this expanding field. Surgical and wound care complications remain a major cause of post-operative mortality. Materials used for these applications need to withstand various mechanical deformations and movements while remaining strongly attached to the intended tissue.

A simple route to tissue adhesives has recently been described involving silica nanoparticles acting as physical adhesive layer between tissues. New research from the Hermann group at the Swiss Federal Laboratories for Materials Science and Technology has expanded upon this concept with a new article published in Nanoscale. The researchers produce a library of inorganic oxide nanoparticles using a scalable and sterile flame spray pyrolysis method. The particles are then used study how different combinations of nanoparticles affect performance as tissue adhesives and also the toxicity of the resulting tissue adhesive materials.

An optimal composition of a mixture of bioglass and silica nanoparticles were found to have exceptionally strong procoagulant and adhesive properties whilst also maintaining superior cyto-compatibility. This highly modular synthetic method paves the way for use of metal oxide nanoparticles as bioactive adhesives in a range of exciting surgical and regenerative medicine applications.

Fig. 1. Inorganic nanoparticles and their use as tissue adhesives

Alexander Cook is a guest web writer for the RSC journal blogs. He is a PhD researcher in the Perrier group at the University of Warwick, focusing on polymer materials and their use in various applications. Follow him on twitter @alexcook222

A new photo-induced polymer crosslinking strategy has been used to produce optoelectronic devices with improved performance by a group of Chinese researchers. This has allowed quantum dot LED devices to be fabricated on flexible plastic substrates as the scientists can avoid high temperature thermal annealing.

Developed at Soochow University and Shanghai Jiaotong University, the researchers believe this crosslinking strategy provides an excellent general method for improving film quality in solution-processed multi-layer LEDs and optoelectronic devices.

The improved efficiency of the devices has been ascribed to superior film surface morphology of the device layers, as the range of non-orthogonal solvents able to be used for solution processing is greatly broadened due to layer crosslinking. The device is based on a hole transport layer of conjugated polymer poly[(9,9-dioctylfluorenyl-2,7-diyl)-alt-(4,4’-(N-(4-butylphenyl)))] (TFB), which is crosslinked with a bifunctional benzophenone, with the crosslinked hole transport layer device giving a 2 times higher efficiency than the device without layer crosslinking.

Fig. 1. New photochemical crosslinking method enables fabrication of novel all-solution-processed multilayer optoelectronic devices to improve device performance using both orthogonal and non-orthogonal solvents.

Read the article:

Crosslinked conjugated polymers as hole transport layers in high-performance quantum dot light-emitting diodes

Yatao Zou, Ying Liu, Muyang Ban, Qi Huang, Teng Sun, Qing Zhang,* Tao Song* and Baoquan Sun*

Nanoscale Horizons, 2017, DOI: 10.1039/C6NH00217J

Alexander Cook is a guest web writer for the RSC journal blogs. He is a PhD researcher in the Perrier group at the University of Warwick, focusing on polymer materials and their use in various applications. Follow him on twitter @alexcook222

Cancer remains the leading cause of death worldwide. Therefore, the importance of early screening of cancer can aid in the prevention and treatment. However, early onset of cancers can often produce limited or no symptoms. In this regard, researchers have turned their attention to miRNA biomarkers found in serum as potential biomarkers for cancer detection. At the onset of cancer, miRNA biomarkers often present at very low concentrations representing a big challenge for researchers to develop analytical tools that can achieve the sensitivity required.

Researchers from Nanjing, China and Georgia, USA have investigated surface enhanced Raman scattering (SERS) as a viable technique for the detection of 3 miRNA biomarkers related to lung cancer. To achieve this, the researchers used a silver nanorod (AgNR) array to provide the plasmonic enhancement required for SERS. The substrate was subsequently functionalised with molecular beacons (MBs) containing different Raman reporters (ROX, Cy5 and FAM) that are complementary to the miRNA targets. In the absence of miRNA target, the SERS signal remains high since the MBs, and, therefore, the Raman reporters, are orientated close to the AgNR substrate. However, when the MBs hybridise to the target sequence, the SERS signal drops in a concentration-related manner allowing quantitation of the target miRNAs in buffer and human serum. The limits of detection for the 3 biomarkers, miRNA-21/486/375, were 393, 176 and 144 aM, respectively.

This research highlights the advantages of using SERS for biomarker detection. The low sensitivity and ability to multiplex make SERS a promising analytical technique for future clinical analyses for cancer detection and other diseases.

Scheme 1 Schematic illustration of the preparation and application of the molecular beacon functionalized-SERS sensor for simultaneously measuring multiple miRNAs.

An ultrasensitive SERS sensor for simultaneous detection of multiple cancer-related miRNAs
C. Y. Song, Y. J. Yang, B. Y. Yang, Y. Z. Sun, Y. P. Zhao and L. H. Wang
Nanoscale, 2016, 8, 17365-17373

Dr Lee Barrett is a guest web writer for the Nanoscale blog. Lee is currently a postdoctoral researcher in the Centre for Molecular Nanometrology at the University of Strathclyde. His research is currently focused on the development of nanoparticle-based sensors and surface enhanced Raman scattering (SERS). Follow him on twitter @L_Bargie