Bio-Nano Interactions : Synthesis, Functionalization and Characterization of Biomaterial Interfaces

Cai, Yixiao

January 2016

Current strategies for designing biomaterials involve creating materials and interfaces that interact with biomolecules, cells and tissues.  This thesis aims to investigate several bioactive surfaces, such as nanocrystalline diamond (NCD), hydroxyapatite (HA) and single crystalline titanium dioxide, in terms of material synthesis, surface functionalization and characterization. Although cochlear implants (CIs) have been proven to be clinically successful, the efficiency of these implants still needs to be improved. A CI typically only has 12-20 electrodes while the ear has approximately 3400 inner hair cells. A type of micro-textured NCD surface that consists of micrometre-sized nail-head-shaped pillars was fabricated. Auditory neurons showed a strong affinity for the surface of the NCD pillars, and the technique could be used for neural guidance and to increase the number of stimulation points, leading to CIs with improved performance. Typical transparent ceramics are fabricated using pressure-assisted sintering techniques. However, the development of a simple energy-efficient production method remains a challenge. A simple approach to fabricating translucent nano-ceramics was developed by controlling the morphology of the starting ceramic particles. Translucent nano-ceramics, including HA and strontium substituted HA, could be produced via a simple filtration process followed by pressure-less sintering. Furthermore, the application of such materials as a window material was investigated. The results show that MC3T3 cells could be observed through the translucent HA ceramic for up to 7 days. The living fluorescent staining confirmed that the MC3T3 cells were visible throughout the culture period. Single crystalline rutile possesses in vitro bioactivity, and the crystalline direction affects HA formation. The HA growth on (001), (100) and (110) faces was investigated in a simulated body fluid in the presence of fibronectin (FN) via two different processes. The HA layers on each face were analysed using different characterization techniques, revealing that the interfacial energies could be altered by the pre-adsorbed FN, which influenced HA formation. In summary, micro textured NCD, and translucent HA and FN functionalized single crystalline rutile, and their interactions with cells and biomimetic HA were studied. The results showed that controlled surface properties are important for enhancing a material’s biological performance.

Bioactive surfaces

nanocrystalline diamond

hydroxyapatite

protein secondary structure

protein absorption

auditory neurons

single crystalline rutile

nano morphology

surface functionalisation

in vitro biomineralisation

translucent nano-ceramics

bio-window material

material characterisation.

Synthesis, Characterization and Photophysical Studies of Porphyrin and N-Confused Porphyrin Derivatives and Self-assembled Nano-Morphologies

Acharya, Rajendra

19 August 2013

No description available.

Chemistry

Organic Chemistry

Porphyrin

N-Confused Porphyrin

Synthesis and Characterization

1D and 2D NMR

Mass Spectrometry

Absorption and Emission Spectroscopy

H-bonding

pi-pi stacking

Self-assembly

Nano-morphology

IR

DSC

TEM

TCSPC

Conception de surfaces bio-inspirées à mouillabilité contrôlée à partir de polymères conducteurs / Conception of bioinspired surfaces with controlled wettability from conducting polymers

Mortier, Claudio

18 December 2017

Le contrôle de la mouillabilité de surface est un enjeu majeur pour le développement de matériaux innovants liés aux nano, bio et smart technologies. La mouillabilité est fonction de deux paramètres majeurs : l’énergie de surface du matériau et sa morphologie. La combinaison de ces deux paramètres est à la base de phénomènes tels que la super/parahydrophobie ou la superoléophobie. Ces capacités extrêmes à repousser les liquides avec soit une forte ou faible adhésion sont des propriétés de surface très intéressantes pour de multiples applications industrielles. La présente thèse propose l’étude d’une série de dérivés du polypyrrole élaborés par électrodéposition permettant d’influencer les paramètres régissant la mouillabilité de surface. Par cette approche, il a été possible d’élaborer des surfaces aux morphologies diverses avec une gamme de mouillabilité complète. Les différentes fonctionnalisations par des groupements hydrophobes greffés sur différentes positions préférentielles du monomère ont conduit à l’élaboration de surfaces para et superhydrophobes mettant en évidence l’impact de l’énergie de surface et de la morphologie sur la mouillabilité. Des études préliminaires ont mis en évidence la possibilité d’obtenir des morphologies variées allant de sphères jusqu’à des fibres à l’échelle du micro/nanomètre. Finalement, ces travaux contribuent à un contrôle en amont de la mouillabilité et de la morphologie de surface pour de nombreuses applications potentielles comme les matériaux collecteurs d’eau, les membranes séparatrices de liquide ou bien les revêtements auto nettoyant. / The control of the surface wettability is a key point for the development of innovative materials in several domains such as nano-, bio- and smart-technologies. The wettability is a function of two main parameters of the materials, such as the surface energy and the surface morphology. The combination of these two parameters allows to observe wetting phenomena as super/parahydrophobicity and superoleophobicity. These extreme abilities to repel liquids with different adhesion behaviors are very interesting properties for several industrial applications. This work presents a series of polypyrrole derivatives elaborated by electrodeposition allowing to influence the parameters driving the surface wettability. Following this approach, it was possible to develop surfaces with several types of morphology and different wetting behaviors from a low to high wettability. The different functionalizations using hydrophobic compounds grafted on various preferential positions on the monomer core yielded to para and superhydrophobic surfaces showing the impact of the surface energy and morphology on the wettability. Thanks to preliminary studies, it was showed the possibility to obtain several morphologies from spherical aggregates to fibers at the micro/nano scale. Finally, this work contributes to an upstream control of the surface wettability and morphologies for many potential applications such as water harvesting, separation membranes and self-cleaning coatings.

Surfaces superhydrophobes

Propriété autonettoyante

Micro/nano morphologie

Mouillabilité

Électrodéposition

Polymérisation radicalaire

Caractérisation de surface

Effet lotus

Effet pétale

Nanotehcnologies

Smart-materials

Superhydrophobic surfaces

Self-cleaning property

Micro/nano morphology

Wettability

Electrodeposition

Radical polymerization

Surface characterization

Lotus effect

Petals effect

Nanotechnologies

Smart-materials