Your search keyword '"Boecking T"' showing total 2 results

1. Biofunctionalization of free-standing porous silicon films for self-assembly of photonic devices

Author

Boecking, T ; https://orcid.org/0000-0003-1165-3122, Kilian, KA ; https://orcid.org/0000-0002-8963-9796, Reece, PJ ; https://orcid.org/0000-0003-4852-3735, Gaus, K ; https://orcid.org/0000-0002-8009-9658, Gal, M, Gooding, JJ ; https://orcid.org/0000-0002-5398-0597, Boecking, T ; https://orcid.org/0000-0003-1165-3122, Kilian, KA ; https://orcid.org/0000-0002-8963-9796, Reece, PJ ; https://orcid.org/0000-0003-4852-3735, Gaus, K ; https://orcid.org/0000-0002-8009-9658, Gal, M, and Gooding, JJ ; https://orcid.org/0000-0002-5398-0597

Abstract

Here we test chemical strategies for the fabrication of free-standing porous silicon thin films that are covalently modified on one of their faces with biorecognition elements to guide the vertical self-assembly of optical structures. Chemical modification via hydrosilylation of alkenes followed by coupling of biomolecules is carried out after the porous silicon film is lifted off from the silicon wafer to avoid damage to the organic monolayer during the lift-off step. Micron-sized biotinylated particles produced from asymmetrically modified porous silicon films are deposited via biorecognition in the correct orientation onto a substrate modified with avidin to form optical resonant microcavities.

Published

2012

2. Statistical predictions on the encapsulation of single molecule binding pairs into sized-dispersed nanocontainers.

Author

Longatte G, Lisi F, Chen X, Walsh J, Wang W, Ariotti N, Boecking T, Gaus K, and Gooding JJ

Subjects

Nanotechnology

Abstract

Single molecule experiments have recently attracted enormous interest. Many of these studies involve the encapsulation of a single molecule into nanoscale containers (such as vesicles, droplets and nanowells). In such cases, the single molecule encapsulation efficiency is a key parameter to consider in order to get a statistically significant quantitative information. It has been shown that such encapsulation typically follows a Poisson distribution and such theory of encapsulation has only been applied to the encapsulation of single molecules into perfectly sized monodispersed containers. However, experimentally nanocontainers are usually characterized by a size distribution, and often just a single binding pair (rather than a single molecule) is required to be encapsulated. Here the use of Poisson distribution is extended to predict the encapsulation efficiency of two different molecules in an association equilibrium. The Poisson distribution is coupled with a log-normal distribution in order to consider the effect of the container size distribution, and the effect of adsorption to the container is also considered. This theory will allow experimentalists to determine what single molecule encapsulation efficiency can be expected as a function of the experimental conditions. Two case studies, based on experimental data, are given to support the theoretical predictions.

Published

2022