Functionalized Materials Based on the Clay Mineral Kaolinite

Fafard, Jonathan

January 2018

The use of kaolinite for preparing functionalized materials for specialized applications is still a relatively niche research subject. This is in spite of its low cost, high availability, and the potential for covalently grafting organic functional groups to its inner and outer surfaces. These grafted compounds have been shown to be highly resistant to heat and solvents, making them very useful for certain applications, for example in polymer nanocomposite materials that require high thermal resistance during polymer processing. Solid state NMR has been shown to play an essential role in solving the structure of functionalized kaolinite materials, however the current knowledge base for these functionalized kaolinites is notably lacking for some nuclei such as 1H, 27Al and 17O. Research was undertaken to address these concerns by developing new synthetic strategies for preparing kaolinite based materials for use as nanocomposites and to examine commonly prepared modified kaolinite precursors materials by 1H and 27Al MAS NMR in an attempt to demonstrate their utility for characterizing kaolinite intercalated and grafted complexes. Solid state 1H NMR of a natural kaolinite, kGa-1b, identified two main proton signals attributed to inner and inner surface hydroxyl protons. The different affinity of these two types of hydroxyl groups towards exchange with deuterium was used to differentiate between the two. The 1H NMR spectra of a DMSO intercalated kaolinite, kDMSO, and a methanol grafted kaolinite, kmethoxy, were fitted with high accuracy using models consistent with the known structures of these materials. The 27Al MAS NMR spectra of a natural kaolinite, kGa-1b, a DMSO intercalated kaolinite, kDMSO, and a methanol grafted kaolinite, kmethoxy measured at 21.1T showed little difference between one another, while noticeable differences could be seen at 4.7T. 27Al MQMAS experiments found almost no difference between these materials in the multiple quantum dimension, suggesting the differences that were observed are a result of differences in quadrupolar parameters rather than chemical shifts. The 27Al NMR spectra of kGa-1b, kDMSO and kmethoxy were fitted with good accuracy using models consistent with known structures of these materials. Different Al(III) sites with CQ values varying by up to 0.6MHz were found. The 27Al NMR spectra of two different methanol grafted kaolinites were also compared and it was found that the intensities of the sites with lower values of CQ were dependent on the quantity of grafted aluminum sites. The interlayer space of kaolinite was functionalized with a block copolymer: poly(ethylene)-block-poly(ethylene glycol) using a kaolinite pre-intercalated with DMSO, kDMSO, and with a biodegradable polymer: poly(lactide) using a kaolinite pre-intercalated with urea, kurea, both by using melts of the polymer. The polymers were found to completely displace their precursors from the interlayer space giving a monolayer type arrangement of the polymer. Attempts were made to graft compounds containing polymerizable functional groups: 3-allyloxy-1,2-propanediol and ethylene glycol vinyl ether to kaolinite’s inner surfaces using a kaolinite pre-intercalated and grafted with methanol, kmethoxy, and a kaolinite pre-intercalated with DMSO, kDMSO, respectively. Both compounds were found to displace their precursors from the interlayer space, adopting a monolayer type arrangement. 13C and 29Si NMR results suggest 3-allyloxy-1,2-propanediol’s allyl group remains intact and partially keys into the clay mineral’s siloxane rings. Ethylene glycol vinyl ether was found to undergo intramolecular cyclization to form an acetal product, consuming its vinyl group in the process. This reaction was observed using an unmodified kaolinite, kGa-1b, suggesting that the clay mineral’s surfaces, both inner and outer, act as an acid catalyst.

Kaolinite

Clay mineral

Intercalation

Nanocomposite

Solid state NMR

XRD

FTIR

TGA

Polymer

Poly(lactide)

Poly(ethylene glycol)

Block copolymer

Melt intercalation

Solid state 1H NMR

Solid state 27Al NMR

Covalent grafting

Přímá syntéza vysokomolekulárních polymerů kyseliny mléčné / Direct Synthesis of High-Molecular Polymers of Lactic Acid

Mikulík, David

January 2016

This master thesis deals with the direct synthesis of polymers from lactic acid. The theoretical part focuses on both natural and synthetic ways of production the lactic acid monomer, their advantages and properties. Furthermore, the theoretical part focuses on the synthesis of poly(lactic acid) (PLA) from lactide, and direct polycondensation from lactic acid discussing about influences of catalysts, co-catalysts as well as chain extenders. The experimental part focuses on the synthesis of PLA polymers and co-polymers wherein investigates suitable catalysts, reaction medium for azeotropic dehydration and co-catalyst influence on products. Thermal and analytical analysis of PLA polymers are mentioned at the end of the experimental part.

New developments in green asymmetric catalysis : Application to Michael reaction and ring opening polymerisation / Nouveaux développements en catalyse asymétrique verte : application à la réaction de Michael et à la polymérisation par ouverture de cycle

Chen, Li

18 July 2016

La synthèse asymétrique organo-catalysée est un domaine de recherche en pleine expansion visant une chimie plus verte. Nous nous sommes intéressés au développement d’une réaction de Michael asymétrique organocatalysée en mettant à profit la catalyse par liaison hydrogène et l’activation énamine afin de contrôler en une seule étape la formation d’adduits portant un centre carboné quaternaire à partir de cétones non activées. Ainsi, nous avons développé des organocatalyseurs bifonctionnels de type squaramide qui ont permis d’obtenir les adduits de Michael attendu à partir de cycloalcanones alpha-substituées avec une bonne énantiosélectivité et une grande régiosélectivité dans un processus sous micro-ondes et sans solvant. Nous avons développé de nouveaux systèmes catalytiques sur la base du motif squaramide qui sont simples, efficaces et opérationnels. Nous avons étudié également l'utilité de nos systèmes organocatalytiques dans d'autres transformations comme la polymérisation verte. Afin de réduire l'utilisation de métaux toxiques pour produire des polymères bien définis sans trace de métaux et d'importance environnementale ou médicale, nous avons également étudié comment nos organo-catalyseurs de type squaramide pourraient contrôler la polymérisation verte par ouverture de cycle. Les systèmes organocatalytiques basés sur des squaramides étaient également applicables à la polymerisation par ouverture de cycle afin de donner des polylactides de dispersité étroite et de masses moléculaires contrôlées. / Organocatalyzed asymmetric synthesis is a growing and rapidly expanding research field for a greener chemistry. In this respect, we were interested in developing an organocatalyzed asymmetric Michael reaction taking advantage of H-bond catalysis and enamine activation allowing control of quaternary carbon center from unactivated ketones. Hence compared with well-known H-bond donor urea and thiourea organocatalysts, we first propose bifunctional squaramide organocatalysts for the one-pot transformation of unsymmetrical ketones to produce Michael adducts exhibiting a stereocontrolled quaternary carbon center in a neat microwave process. We also developped new catalytic systems based on the squaramide motive that are efficient and operationnaly simple, and produce Michael adducts in a good regioselectivity with an excellent enantio-selectivity. We also studied the usefulness of our systems in other transformations like green polymerization. In order to reduce the use of toxic metals to produce metal-free and well-defined polymers of environmental and medical significance, we also studied how our squaramide organocatalysts could control the green ring opening polymerization (ROP.The squaramide organocatalyst-based systems were also applicable to ROP to give polylactides of narrow dispersity and controlled molecular masses.

Michael asymétrique

Polymérisation par ouverture de cycle

Centres carbonés quaternaires

Micro-Ondes

Lactides

Aymmetric Michael reaction

Ring opeing polymerisation

Squaramide bifunctional organocatalysts

Quaternary carbon centers

Microwave

Lactide

Healing properties of surface-coated polycaprolactone-co-lactide scaffolds: A pilot study in sheep

Rentsch, Claudia, Schneiders, Wolfgang, Hess, Ricarda, Rentsch, Barbe, Bernhardt, Ricardo, Spekl, Kathrin, Schneider, Konrad, Scharnweber, Dieter, Biewener, Achim, Rammelt, Stefan

11 October 2019

The aim of this pilot study was to evaluate the bioactive, surface-coated polycaprolactone-co-lactide scaffolds as bone implants in a tibia critical size defect model. Polycaprolactone-co-lactide scaffolds were coated with collagen type I and chondroitin sulfate and 30 piled up polycaprolactone-co-lactide scaffolds were implanted into a 3 cm sheep tibia critical size defect for 3 or 12 months (n¼5 each). Bone healing was estimated by quantification of bone volume in the defects on computer tomography and microcomputer tomography scans, plain radiographs, biomechanical testing as well as by histological evaluations. New bone formation occurred at the proximal and distal ends of the tibia in both groups. The current pilot study revealed a mean new bone formation of 63% and 172% after 3 and 12 months, respectively. The bioactive, surface coated, highly porous three-dimensional polycaprolactone-co-lactide scaffold stack itself acted as a guide rail for new bone formation along and into the implant. These preliminary data are encouraging for future experiments with a larger group of animals.

info:eu-repo/classification/ddc/610

ddc:610

Photo-Catalytic Reaction Screening and Catalytic Polymerization of rac-Lactide Studied by Mass Spectrometry

Jayaraj, Savithra

January 2021

No description available.

Chemistry

Mass Spectrometry

Small Molecules

Photoreaction Screening

heterocyclic compounds

Tetrahydroquinoline

Tetrahydroisoquinoline

Synthesis

Catalysis

Photocatalytic reactions

Screening

Ruthenium

Fullerene

Polylactide

polymerization

PLA

Lactide

heterogeneous catalysis

Green Chemistry

dimerization

dehydro dimerization

photo oxygenation

Fabrication, Characterisation and Optimisation of Biodegradable Scaffolds for Vascular Tissue Engineering Application of PCL and PLGA Electrospun Polymers for Vascular Tissue Engineering

Bazgir, Morteza

January 2021

Annually, about 80,000 people die in the United Kingdom due to myocardial infarction, congestive heart failure, stroke, or from other diseases related to blood vessels. The current gold standard treatment for replacing the damaged blood vessel is by autograft procedure, during which the internal mammary artery (IMA) graft or saphenous vein graft (SVG) are usually employed. However, some limitations are associated with this type of treatment, such as lack of donor site and post-surgery problems that could negatively affect the patient’s health. Therefore, this present work aims to fabricate a synthetic blood vessel that mimics the natural arteries and to be used as an alternative method for blood vessel replacement. Polymeric materials intended to be used for this purpose must possess several characteristics including: (1) Polymers must be biocompatible; (2) Biodegradable with adequate degradation rate; (3) Must maintain its structural integrity throughout intended use; (4) Must have ideal mechanical properties; and (5) Must encourage and enhance the proliferation of the cells. The feasibility of using synthetic biodegradable polymers such as poly (ε- caprolactone) (PCL) and poly (lactide-co-glycolic acid) (PLGA) for fabricating tubular vascular grafts was extensively investigated in this work. Many fundamental experiments were performed to develop porous tissue- engineered polymeric membranes for vascular graft purposes through electrospinning technique to achieve the main aim. Electrospinning was selected since the scaffolds produced by this method usually resemble structural morphology similar to the extracellular matrix (ECM). Hence, four 6mm in diameter tubular shape vascular grafts PCL only, PLGA only, coaxial (core-PCL and shell-PLGA), and bilayer (inner layer-PCL and outer layer-PLGA) was designed and fabricated successfully. The structure and properties of each scaffold membrane were observed by scanning electron microscopy (SEM), and these scaffolds were fully characterized by Fourier-transform infrared spectroscopy (FT-IR), X-ray diffraction (XRD), thermogravimetric analysis (TGA), water contact angle measurements, mechanical tensile test, as well as cell culture studies were carried out by seeding human umbilical vein cells (HUVEC) and human vascular Fibroblast cells (HVF). Moreover, all polymeric grafts underwent degradation process, and the change in their morphological structure properties was studied over 12 weeks at room temperature. All scaffolds were also exposed to a controlled temperature of 37°C for four weeks, in phosphate-buffered saline solution (pH, 7.3). It was found that all scaffolds displayed exceptional fibre structure and excellent degradability with adequate steady weight-loss confirming the suitability of the fabricated scaffolds for tissue engineering applications. The coaxial and bilayer scaffolds degraded at a much slower (and steadier) rate than the singular PCL and PLGA tubular scaffolds. Coaxial grafts fabricated via coaxial needle showed an increase in their fibre diameter and pore size volume than other membranes, but also showed to have significant tensile strength, elongation at fracture, and Young’s modulus. To conclude, all scaffolds have demonstrated to be reliable to adhere and proliferate HUVEC, and HVF cells, but these cells were attracted to the PLGA membrane more than other fabricated membranes.

Tubular vascular graft (TVG)

Polycaprolactone (PCL)

Poly (lactide-co-glycolic acid) (PLGA)

Degradation

Electrospinning

Nanofibres

Human vascular fibroblast cells (HVF)

Tensile test

Fabrication

Biodegradable scaffolds

Vascular tissue engineering

Sulfonamide supported catalysts for the ring opening polymerisation of cyclic esters

Schwarz, Andrew Douglas

January 2010

This Thesis describes the synthesis and characterisation of sulfonamide supported titanium, zirconium and aluminium complexes and their use as ring opening polymerisation catalysts for ε-caprolactone and rac-lactide. Chapter 1 introduces polyester use, development and characterisation in general. Metal catalysed ring opening polymerisation of cyclic esters is considered in a literature review of the field. Titanium, zirconium and aluminium complexes supported by polydentate sulfonamide ligands are also discussed. Chapter 2 describes the synthesis and characterisation of new sulfonamide supported titanium amide, isopropoxide and zirconium isopropoxide complexes. Their application as catalysts for the ring opening polymerisation of ε-caprolactone and rac-lactide is discussed and compared with known zirconium isopropoxide complexes supported by bis(phenolate) amine ligands. Chapter 3 describes the synthesis and characterisation of Cs symmetric titanium amide and alkoxide complexes supported by dianionic, tri- and tetradentate sulfonamide ligands. Zirconium alkyl and amide complexes supported by C3- symmetric trianionic ‘tren’ type ligands bearing three different sulfonamide groups are also presented. The application of these complexes for the ring opening polymerisation of ε-caprolactone and rac-lactide is described and compared with the complexes presented in Chapter 2. Chapter 4 provides an overview of the synthesis and characterisation of aluminium alkoxide and alkyl complexes supported by dianionic, tri- and tetradentate sulfonamide ligands. Solution state behaviour and solid state structures are presented and discussed. An assessment of these complexes for the ring opening polymerisation of rac-lactide is presented. Chapter 5 presents full experimental procedures and characterisation data for the new complexes reported. CD Appendix contains .cif files for all new crystallographically characterised complexes described, and additional polymerisation graphs.

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