Nano-On-Nano: Responsive Nanosubstrate-Mediated Liposome Delivery with High Cellular Uptake Efficiency

Efficiently delivering liposomal content to cells in a relatively uniform dose and patterned fashion, especially bypassing the degradative endocytosis pathway, is an important technology in cell culture and potentially to tissue engineering that still remains challenging. We developed a “nano-on-nano” platform technology that consists of the following three material features: (1) high density silicon nanopillars to create a pseudo-3-dimensional nanoenvironment for cell culturing, (2) thermoresponsive polymer grafted onto silicon nanopillars to form a responsive nanosubstrate, and (3) immobilized liposomes using a biotin-streptavidin-biotin conjugation. The working principle is that the liposomes are detached for cellular uptake upon thermal stimulation and high local liposome concentration between the cells and substrates drives the cellular uptake with nonendocytic pathways. Cryo-EM images confirms that liposomes are attached to form liposome-warped nanopillars. Upon thermal stimulation, an 8 times higher increase in the liposomal fluorescence intensity is observed compared to the conventional solution-phase liposome delivery, indicating that high local concentration drives liposome uptake with greater efficiency. Moreover, preliminary mechanistic studies reveal that these liposomes are taken up by nonendocytic pathways. The ability of our nano-on-nano delivery system that achieves efficient dose-uniform cellular delivery can open a unique era in cell and tissue engineering by controlling cell behaviors with the delivery of bioactive ingredient-loaded liposomes

Table_1_Organic Electrochemical Transistors/SERS-Active Hybrid Biosensors Featuring Gold Nanoparticles Immobilized on Thiol-Functionalized PEDOT Films.doc

In this study we immobilized gold nanoparticles (AuNPs) onto thiol-functionalized poly(3,4-ethylenedioxythiophene) (PEDOT) films as bioelectronic interfaces (BEIs) to be integrated into organic electrochemical transistors (OECTs) for effective detection of dopamine (DA) and also as surface-enhanced Raman scattering (SERS)—active substrates for the selective detection of p-cresol (PC) in the presence of multiple interferers. This novel PEDOT-based BEI device platform combined (i) an underlying layer of polystyrenesulfonate-doped PEDOT (PEDOT:PSS), which greatly enhanced the transconductance and sensitivity of OECTs for electrochemical sensing of DA in the presence of other ascorbic acid and uric acid metabolites, as well as amperometric response toward DA with a detection limit (S/N = 3) of 37 nM in the linear range from 50 nM to 100 μM; with (ii) a top interfacial layer of AuNP-immobilized three-dimensional (3D) thiol-functionalized PEDOT, which not only improved the performance of OECTs for detecting DA, due to the signal amplification effect of the AuNPs with high catalytic activity, but also enabled downstream analysis (SERS detection) of PC on the same chip. We demonstrate that PEDOT-based 3D OECT devices decorated with a high-density of AuNPs can display new versatility for the design of next-generation biosensors for point-of-care diagnostics.</p