High resolution imaging of bio-molecular binding studies studies using a Widefield surface Plasmon Microscope.

Denyer, Morgan C.T., Jamil, M.M. Abdul, Twigg, Peter C., Youseffi, Mansour, Britland, Stephen T., Liu, S., See, Chung Wah, Zhang, J., Sommekh, M.G.

14 September 2009

Surface plasmon microscopes are mostly built around the prism based Kretschmann configuration. In these systems, an image of a sample can be obtained in terms of an intensity map, where the intensity of the image is dependent on the coupling of the light into the surface plasmons. Unfortunately the lateral resolution of these systems relies on the ability of plasmons to propagate along the metallised layer and is usually limited to a few microns unless special measures are taken. The widefield surface plasmon microscope (WSPR), used here enables surface plasmon imaging at significantly higher lateral resolutions than prism based systems. In this study we demonstrate the functionality of the WSPR by imaging a sequence of binding events between micro-patterned extracellular matrix proteins and their specific antibodies. Using the WSPR system a change in contrast was observed with each binding event. Images produced via the WSPR system were analyzed and compared qualitatively and quantitatively. Consequently, we confirm that the WSPR microscope described here can be used to study sequential monomolecular layer binding events on a micron scale. These results have significant implications in the development of new micron scale bioassays.

Bio-molecular interaction

Micro-contact printing

Surface plasmons

High resolution

Electroluminescent devices via soft lithography

Young, Richard James Hendley

January 2017

This thesis provides a compendium for the use of microcontact printing in fabricating electrical devices. Work has been undertaken to examine the use of soft lithographic techniques for employment in electronic manufacture. This thesis focusses on the use of high electric field generators as a means to producing electroluminescent devices. These devices provide a quantifiable output in the form of light. Analysis of the electrical performance of electrode structures can be determined by their success at producing light. A prospective reduction in driving voltage would deem these devices more efficient, longer lasting and an improvement on current specification. The work focussed on the viability of using relatively crude print techniques to create high resolution structures. This was carried out successfully and demonstrated that lighting structures of 75 μm and 25 μm have been produced. Microcontact printing has been established as a method for patterning gold surfaces with a functionalising self-assembled monolayer using alkanethiol molecules. This layer is then utilised as an etch resist layer to expose gold tracks for use as electric field generator electrode arrays. Through careful analysis of each step of the printing process, techniques were developed and reported to create a robust and repeatable print mechanism for reliability and accuracy. These techniques were employed to optimise the print process culminating in the development of each stage and final electrode structures mounted on a rigid backplate for use as electroluminescent devices for characterisation. These devices were then modelled for their electrical characteristics and investigated for being used in low voltage application. In this case for the development of electroluminescent applications, a driving voltage of 65 V was achieved and represents a significant advance to the field of printed electronics and Electroluminescence.

Investigations into botanical contact printing (where the light meets the trees; thirteen variations)

Manwiller, Christine Marie

01 May 2018

Investigations in Botanical Contact Printing (Where the Light Meets the Trees; Thirteen Variations) explores the process of botanical contact printing on paper, culminating in a series of thirteen handmade artist books. Each of the thirteen books contains a poem from a collection of thirteen poems written by Alice Yousef. Every element of the book: materials, structure, calligraphed text, type of botanical contact print, sometimes the enclosure, responds to the poem, providing a visual interpretation of the written word. The completely different approaches to binding structure in this series intend to not only visually support the text, but also explore the possibilities of botanical contact print imagery in the book form.

Artist books

Book Arts

Bookbinding

Botanical Contact Printing

Natural dyeing

Poetry

Book and Paper

Synthesis and electrochemical studies of nitroxide radical polymer brushes via surface-initiated atom transfer radical polymerization

Wang, Yu-Hsuan

27 July 2010

A non-crosslinking approach that covalently bonds nitroxide polymer brushes onto the ITO substrates via surface-initiated atom transfer radical polymerization (ATRP) was develpoed. Since the indium tin oxide (ITO)-silane covalent bonding providesvery strong chemical bonds to adsorb the nitroxide polymer brushes on ITO, it prevents polymers from dissolving into electrolyte solvent and thus improves its electrochemical properties. Moreover, micro-contact printing technology was used to pattern nitroxide polymer brushes on an ITO surface for the potential application in microbatteries. The morphology of electrodes was observed by atomic force microscopy.The electrochemical properties of the cathode were also studies.

micro-contact printing

organic radical battery

thin film electrode

atom transfer radical polymerization

polymer brushes

High resolution imaging of bio-molecular binding studies using a widefield surface plasmon microscope

Jamil, M. Mahadi Abdul, Youseffi, Mansour, Twigg, Peter C., Britland, Stephen T., Liu, S., See, C.W., Zhang, J., Somekh, M.G., Denyer, Morgan C.T.

January 2008

Surface plasmon microscopes are mostly built around the prism based Kretschmann configuration. In these systems, an image of a sample can be obtained in terms of an intensity map, where the intensity of the image is dependent on the coupling of the light into the surface plasmons. Unfortunately the lateral resolution of these systems relies on the ability of plasmons to propagate along the metallised layer and is usually limited to a few microns unless special measures are taken. The widefield surface plasmon microscope (WSPR), used here enables surface plasmon imaging at significantly higher lateral resolutions than prism based systems. In this study we demonstrate the functionality of the WSPR by imaging a sequence of binding events between micro-patterned extracellular matrix proteins and their specific antibodies. Using the WSPR system a change in contrast was observed with each binding event. Images produced via the WSPR system were analyzed and compared qualitatively and quantitatively. Consequently, we confirm that the WSPR microscope described here can be used to study sequential monomolecular layer binding events on a micron scale. These results have significant implications in the development of new micron scale bioassays.

Investigation of Pulse electric field effect on HeLa cells alignment properties on extracellular matrix protein patterned surface

Jamil, M. Mahadi Abdul, Zaltum, M.A.M., Rahman, N.A.A., Ambar, R., Denyer, Morgan C.T., Javed, F., Sefat, Farshid, Mozafari, M., Youseffi, Mansour

27 June 2018

Yes / Cell behavior in terms of adhesion, orientation and guidance, on extracellular matrix (ECM) molecules including collagen, fibronectin and laminin can be examined using micro contact printing (MCP). These cell adhesion proteins can direct cellular adhesion, migration, differentiation and network formation in-vitro. This study investigates the effect of microcontact printed ECM protein, namely fibronectin, on alignment and morphology of HeLa cells cultured in-vitro. Fibronectin was stamped on plain glass cover slips to create patterns of 25μm, 50μm and 100μm width. However, HeLa cells seeded on 50μm induced the best alignment on fibronectin pattern (7.66° ±1.55SD). As a consequence of this, 50μm wide fibronectin pattern was used to see how fibronectin induced cell guidance of HeLa cells was influenced by 100μs and single pulse electric fields (PEF) of 1kV/cm. The results indicates that cells aligned more under pulse electric field exposure (2.33° ±1.52SD) on fibronectin pattern substrate. Thus, PEF usage on biological cells would appear to enhance cell surface attachment and cell guidance. Understanding this further may have applications in enhancing tissue graft generation and potentially wound repair. / Ministry of Higher Education Malaysia and UTHM Tier 1 Research Grant (U865)

HeLa

Cells alignment

Pulse electric field

Micro contact printing

Extra cellular matrix

Cell proliferation

Cell guidance

Understanding the Structure and Properties of Self-Assembled Monolayers for Interfacial Patterning

Adamczyk, Leslie Ann

29 June 2009

This dissertation describes the impact of defects on monolayer properties for self-assembled monolayers (SAMs) created by interfacial patterning methods. When forming a two-dimensional interfacial pattern with n-alkanethiols on gold, the desired electrochemical properties are those of a homogeneous, solution adsorbed monolayer. However, even well-ordered SAMs contain a small degree of defects, especially at domain boundaries where two nucleating domains converge. Patterning a surface creates user-defined domain boundaries within the monolayer, potentially having a significant impact on the properties of the interface. This dissertation investigates the effect that user-created domain boundaries have on the properties of a monolayer, as studied by electrochemical impedance spectroscopy. Two patterning methods are investigated for creating user-defined domain boundaries: the soft lithography method of contact printing and site-selective reductive desorption. The electrochemical properties of homogeneous contact printed monolayers are measured and compared to those of monolayers prepared by solution adsorption. The contact printed monolayers are found to have dramatically different impedance behavior from the solution prepared monolayers, consistent with the contact printed monolayers having greater defect density. In addition, these studies show that the overall defect density depends on the concentration of the solutions used for contact printing. In this work, simple patterns are created by contact printing a pattern onto the substrate and then backfilling the remaining gold substrate by solution adsorption. Backfilling with the same alkanethiol used to create the pattern generates a homogeneous monolayer; however, it is found that the contact printed/backfilled monolayer has an impedance intermediate between the homogeneous contact printed and the homogeneous solution adsorbed monolayer. This result suggests that the backfilling process also saturates the pinhole defects associated with the contact printed areas. In addition to exploring defects that arise from contact printing, simple patterns with user-defined defects, created by site-selective reductive desorption (SSRD), were also investigated. Following the backfill step, the impedance behavior of the SSRD produced patterns was similar to that of the impedance of the initial pattern before backfilling. This important result implies that the domain boundaries play the most important role in defining the overall impedance of the patterned interface. / Ph. D.

electrochemical impedance spectroscopy

contact printing

electrochemistry

self-assembled monolayers

defects

patterns

Fabrication of Tissue Precursors Induced by Shape-changing Hydrogels

Akintewe, Olukemi O.

01 January 2015

Scaffold based tissue reconstruction inherently limits regenerative capacity due to inflammatory response and limited cell migration. In contrast, scaffold-free methods promise formation of functional tissues with both reduced adverse host reactions and enhanced integration. Cell-sheet engineering is a well-known bottom-up tissue engineering approach that allows the release of intact cell sheet from a temperature responsive polymer such as poly-N-isopropylacrylamide (pNIPAAm). pNIPAAm is an ideal template for culturing cell sheets because it undergoes a sharp volume-phase transition owing to the hydrophilic and hydrophobic interaction around its lower critical solution temperature (LCST) of 32°C, a temperature close to physiological temperature. Compared to enzymatic digestion via trypsinization, pNIPAAm provides a non-destructive approach for tissue harvest which retains its basal surface extracellular matrix and preserves cell-to-cell junctions thereby creating an intact monolayer of cell sheet suitable for tissue transplantation. The overall thrust of this dissertation is to gain a comprehensive understanding of how tissue precursors are formed, harvested and printed from interactions with shape-changing pNIPAAm hydrogel. A simple geometrical microbeam pattern of pNIPAAm structures covalently bound on glass substrates for culturing mouse embryonic fibroblast and skeletal myoblast cell lines is presented. In order to characterize the cell-surface interactions, three main investigations were conducted: 1) the mechanism of cell detachment; 2) the feasibility of micro-contact printing tissue precursors onto target surfaces; and 3) the assembly of these tissues into three-dimensional (3D) constructs. Detachment of cells from the shape-changing hydrogel was found to correlate with the lateral swelling of the microbeams, which is induced by thermal activation, hydration and shape distortion of the patterns. The mechanism of cell detachment was primarily driven by strain, which occurred almost instantaneously above a critical strain of 25%. This shape-changing pNIPAAm construct allows water penetration from the periphery and beneath the attached cells, providing rapid hydration and detachment within seconds. Cell cultured microbeams were used as stamps for micro-contact printing of tissue precursors and their viability, metabolic activity, local and global organization were evaluated after printing. The formation and printing of intact tissues from the shape-changing hydrogel suggests that the geometric patterning of pNIPAAm directs spatial organization through physical guidance cues while preserving cell functioning. Tissue precursors were sequentially assembled into parallel and perpendicular configurations to demonstrate the feasibility of constructing dense tissues with different organizations such as interconnected cell lines that could induce vascularization to solve perfusion issues in regenerative therapies. The novel approach presented in this dissertation establishes an efficient method for harvesting and printing of tissue precursors that may be applicable for the modular, bottom up construction of complex tissues for organ models and regenerative therapies.

Bioprinting

Cell Alignment

Micro-contact Printing

Poly-N-isopropylacrylamide

Temperature Responsive Hydrogel

Chemical Engineering

Polymer Chemistry

Étude de l'adhésion du collagène sur des surfaces chimiquement modifiées par SPR, AFM et PM-IRRAS

Andersen, Audrée

January 2002

Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal.

Fibrilles

Microscopie à force atomique

Micro-contact printing

Assemblage dirigé d'objets à partir de solutions colloïdales

Genevieve, Mike

04 February 2009

L'intégration de nano-objets dans des systèmes fonctionnels à l'échelle nanométrique est un sérieux challenge à relever pour les applications qui exploitent leurs propriétés uniques. Ces objets peuvent être de natures diverses et variées, des nano-particules, des protéines, des molécules. De nombreuses problématiques visent à assembler sous forme 2D ou 3D ces nano-objets en suspension dans un liquide sur des surfaces solides. Leur intégration depuis cette phase liquide sur une surface solide, demeure une opération sensible. Une attention toute particulière est alors mise sur l'assemblage de biomolécules ou de nano-particules pour des applications tournées vers l'analyse biologique et le diagnostic médical, mais aussi vers la fabrication de systèmes micro-nano systèmes électromécaniques spécialisés. Le travail présenté dans cette thèse s'inscrit dans cette problématique, il consiste à étudier, comprendre et modéliser les mécanismes physiques mis en jeu dans la technique d'assemblage dirigé par capillarité (mouillabilité, piégeage de la ligne triple sur des motifs artificiels, flux convectifs au sein de la solution). Pour cela nous avons conçu et assemblé un système expérimental d'assemblage capillaire. Un volet technologique a également été développé afin de créer des motifs de piégeage par des méthodes de nanolithographie. Le dernier volet du travail de recherche que nous avons effectué est de nature plus applicative, nous montrons comment un tel procédé peut être utilisé afin d'assembler des nano-objets d'intérêt, autres que des nanosphères parfaites. Nous avons en particulier étudié l'assemblage de brins d'ADN permettant leur peignage organisé sur une surface ainsi que l'assemblage de nanotubes de carbone.

Assemblage dirigé

Capillarité

Solution colloïdale

Structuration de surface

Lithographie optique

Lithographie électronique

Micro-contact printing

Nanosphères

Colloïdes

ADN

Nano-tubes de carbones