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by Keyword: Stimuli-responsive


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Llopis-Lorente, A., Garcií-Fernández, A., Murillo-Cremaes, N., Hortelão, A. C., Patinño, T., Villalonga, R., Sancenón, F., Martínez-Máñer, R., Sánchez, S., (2019). Enzyme-powered gated mesoporous silica nanomotors for on-command intracellular payload delivery ACS Nano 13, (10), 12171-12183

The introduction of stimuli-responsive cargo release capabilities on self-propelled micro- and nanomotors holds enormous potential in a number of applications in the biomedical field. Herein, we report the preparation of mesoporous silica nanoparticles gated with pH-responsive supramolecular nanovalves and equipped with urease enzymes which act as chemical engines to power the nanomotors. The nanoparticles are loaded with different cargo molecules ([Ru(bpy)3]Cl2 (bpy = 2,2′-bipyridine) or doxorubicin), grafted with benzimidazole groups on the outer surface, and capped by the formation of inclusion complexes between benzimidazole and cyclodextrin-modified urease. The nanomotor exhibits enhanced Brownian motion in the presence of urea. Moreover, no cargo is released at neutral pH, even in the presence of the biofuel urea, due to the blockage of the pores by the bulky benzimidazole:cyclodextrin-urease caps. Cargo delivery is only triggered on-command at acidic pH due to the protonation of benzimidazole groups, the dethreading of the supramolecular nanovalves, and the subsequent uncapping of the nanoparticles. Studies with HeLa cells indicate that the presence of biofuel urea enhances nanoparticle internalization and both [Ru(bpy)3]Cl2 or doxorubicin intracellular release due to the acidity of lysosomal compartments. Gated enzyme-powered nanomotors shown here display some of the requirements for ideal drug delivery carriers such as the capacity to self-propel and the ability to “sense” the environment and deliver the payload on demand in response to predefined stimuli.

Keywords: Controlled release, Drug delivery, Enzymatic catalysis, Gatekeepers, Nanocarriers, Nanomotors, Stimuli-responsive nanomaterials


Casanellas, Ignasi, García-Lizarribar, Andrea, Lagunas, Anna, Samitier, Josep, (2018). Producing 3D biomimetic nanomaterials for musculoskeletal system regeneration Frontiers in Bioengineering and Biotechnology 6, Article 128

The human musculoskeletal system is comprised mainly of connective tissues such as cartilage, tendon, ligaments, skeletal muscle and skeletal bone. These tissues support the structure of the body, hold and protect the organs, and are responsible of movement. Since it is subjected to continuous strain, the musculoskeletal system is prone to injury by excessive loading forces or aging, whereas currently available treatments are usually invasive and not always effective. Most of the musculoskeletal injuries require surgical intervention facing a limited post-surgery tissue regeneration, especially for widespread lesions. Therefore, many tissue engineering approaches have been developed tackling musculoskeletal tissue regeneration. Materials are designed to meet the chemical and mechanical requirements of the native tissue three-dimensional (3D) environment, thus facilitating implant integration while providing a good reabsorption rate. With biological systems operating at the nanoscale, nanoengineered materials have been developed to support and promote regeneration at the interprotein communication level. Such materials call for a great precision and architectural control in the production process fostering the development of new fabrication techniques. In this mini review, we would like to summarize the most recent advances in 3D nanoengineered biomaterials for musculoskeletal tissue regeneration, with especial emphasis on the different techniques used to produce them.

Keywords: Nanofiber, 3D printing, Musculoskeletal, Regeneration, Scaffold, Tissue Engineering, Stimuli-responsive


Benetti, E., Navarro, M., Zapotoczny, S., Vancso, G. J., (2009). Stimuli-Responsive Polymer Brushes Surface Design: Applications in Bioscience and Nanotechnology (ed. Förch, R. , Schönherr, H. , Jenkins, A.T.A), Wiley-VCH GmbH & Co. KGaA (Weinheim, Germany) , 125-144