Yirij Fedutik scite author profile

Osteoarthritis implies a progressive degeneration of the whole joint. Cartilage is particularly affected, with inflammation playing a pivotal role1. In recent years, cartilage regeneration has been pursued through several bioengineering strategies and using different stem cell types2-6. Adipose -derived mesenchymal stromal cells (ASCs) constitute an intriguing and minimally invasive option. However, the use of ASCs for cartilage regeneration is hampered by a relatively inefficient expression of key chondrogenic markers7. Thus, new strategies to boost both in situ targeting and chondrogenesis of ASCs are highly desirable. Here we show that ASCs embedded in a nanocomposite hydrogel including piezoelectric nanomaterials and graphene oxide nanoflakes, and stimulated with ultrasound waves with precisely controlled parameters (1 MHz and 250 mW/cm2, for 5 min once every two days for a period of 10 days) dramatically boost cell chondrogenic commitment. Furthermore, this stimulation regimen also has a considerable anti-inflammatory effect. The proposed nanocomposite hydrogel also shows excellent biocompatibility in vivo. Our results show for the first time the chondrogenic potential of the combined piezoelectric nanoparticle-ultrasound stimulus; the proposed paradigm has the potential to trigger cartilage regeneration in osteoarthritis, focal cartilage defects and other pathological conditions involving cartilage lesions and degeneration. Future efforts should expand preclinical data, and target clinical applications of this therapeutic strategy.

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Selective Electroless Copper Plating of Ink-Jet Printed Textiles Using a Copper-Silver Nanoparticle Catalyst

Azar

Danilova

Krishnan

et al. 2022

Polymers

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The electroless copper plating of textiles, which have been previously printed with a catalyst, is a promising method to selectively metallise them to produce high-reliability e-textiles, sensors and wearable electronics with wide-ranging applications in high-value sectors such as healthcare, sport, and the military. In this study, polyester textiles were ink-jet printed using differing numbers of printing cycles and printing directions with a functionalised copper–silver nanoparticle catalyst, followed by electroless copper plating. The catalyst was characterised using Transmission Electron Microscopy (TEM) and Ultraviolet/Visible (UV/Vis) spectroscopy. The electroless copper coatings were characterised by copper mass gain, visual appearance and electrical resistance in addition to their morphology and the plating coverage of the fibres using Scanning Electron Microscopy (SEM). Stiffness, laundering durability and colour fastness of the textiles were also analysed using a stiffness tester and Launder Ometer, respectively. The results indicated that in order to provide a metallised pattern with the desired conductivity, stiffness and laundering durability for e-textiles, the printing design, printing direction and the number of printing cycles of the catalyst should be carefully optimised considering the textile’s structure. Achieving a highly conductive complete copper coating, together with an almost identical and sufficiently low stiffness on both sides of the textile can be considered as useful indicators to judge the suitability of the process.

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Yirij Fedutik

Functionalised copper nanoparticle catalysts for electroless copper plating on textiles

Ultrasound stimulation of piezoelectric nanocomposite hydrogels boosts cartilage regeneration

Selective Electroless Copper Plating of Ink-Jet Printed Textiles Using a Copper-Silver Nanoparticle Catalyst

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