Ring-opening polymerization from cellulose for biocomposite applications

Lönnberg, Hanna

January 2009

There is an emerging interest in the development of sustainable materials with high performance. Cellulose is promising in this regard as it is a renewablere source with high specific properties, which can be utilized as strong reinforcements in novel biocomposites. However, to fully exploit the potential ofcellulose, its inherent hydrophilic character has to be modified in order toimprove the compatibility and interfacial adhesion with the more hydrophobicpolymer matrices commonly used in composites.In this study, the grafting of poly(ε-caprolactone) (PCL) and poly(L-lactide)(PLLA) from cellulose surfaces, via ring-opening polymerization (ROP) of ε-caprolactone and L-lactide, was investigated. Both macroscopic and nano-sizedcellulose were explored, such as filter paper, microfibrillated cellulose (MFC),MFC-films, and regenerated cellulose spheres. It was found that thehydrophobicity of the cellulose surfaces increased with longer graft lengths, andthat polymer grafting rendered a smoother surface morphology.To improve the grafting efficiency in the ROP from filter paper, both covalent(bis(methylol)propionic acid, bis-MPA) and physical pretreatment (xyloglucanbisMPA)were explored. The highest grafting efficiency was obtained with ROPfrom the bis-MPA modified filter papers, which significantly increased amountof polymer on the surface, i.e. the thickness of the grafted polymer layer.MFC was grafted with PCL to different molecular weights. The dispersability innon-polar solvent was obviously improved for the PCL grafted MFC, incomparison to neat MFC, and the stability of the MFC suspensions was better maintained with longer grafts. PCL based biocomposites were prepared from neat MFC and PCL grafted MFCwith different graft lengths. The polymer grafting improved the mechanical properties of the composites, and the best reinforcing effect was obtained when PCL grafted MFC with the longest grafts were used as reinforcement.A bilayer laminate consisting of PCL and MFC-films grafted with different PCL graft lengths displayed a gradual increase in the interfacial adhesion with increasing graft length.The effect of grafting on the adhesion was also investigated via colloidal probeatomic force microscopy at different temperatures and time in contact. A significant improvement in the adhesion was observed after polymer grafting. / QC 20100730

cellulose

ring-opening polymerization

polycaprolactone

grafting from

Chemistry

Kemi

Single step production of nanoporous electrospun poly(ε-caprolactone) fibres

Katsogiannis, Konstantinos A. G.

January 2016

Nanoporous polymer fibres are currently attracting increasing interest due to their unique characteristics. Increased specific surface area, improved mechanical properties and improved cellular growth are amongst the advantages that set porous fibres as ideal candidates in applications like catalysis, separation and tissue engineering. This work explores the single step production of porous poly(ε-caprolactone) (PCL) fibres through combinative electrospinning and Non-solvent Induced Phase Separation (NIPS) technique. Theoretical models, based on three different contact models (Hertzian, DMT, JKR), correlating the fibrous network specific surface area to material properties (density, surface tension, Young s modulus, Poisson s ratio) and network physical properties (density) and geometrical characteristics (fibre radius, fibre aspect ratio, network thickness) were developed in order to calculate the surface area increase caused by pore induction. Experimental results proved that a specific surface area increase of up to 56% could be achieved, compared to networks composed of smooth surfaced fibres. The good solvent effect on electrospun fibre surface morphology and size was examined through experimental investigation of four different good solvent (chloroform, dichloromethane, tetrahydrofuran and formic acid) based solutions at various good/poor solvent ratios. Chloroform was proven to be the most suitable solvent for good /poor solvent ratios varying from 75-90% v/v, whereas alternative mechanisms leading to different fibre morphologies were identified, interpreted and discussed. Evaporation rate of the good solvent was identified as the key parameter of the process. Second order polynomial equations, derived from the experimental data, correlating the feed solution physical parameters (viscosity, conductivity, surface tension) to the fibre average diameter produced were developed and validated. Response surface methodology was implemented for the design and conduction of electrospinning experiments on a 12.5 % w/v Chloroform/DMSO solution 90/10 % v/v in order to determine the individual process parameters (spinning distance, applied voltage, solution flow rate) effect in fibre surface morphology and size. The increase in any of these parameters results in increase of both the fibre size and the tendency for pore generation, whereas applied voltage was the parameter with the strongest effect. Findings from this thesis expand the knowledge about both phenomena occurring during the production process and end product properties, and can be used for the production of controlled morphology and size porous poly(ε-caprolactone) (PCL) fibres.

677

Membranas de policaprolactona obtidas por eletrofiação para utilização em engenharia tecidual / Electrospun polycaprolactone membranes for tissue Engineering

Ramos, Sergio Lopes Fernandes

18 August 2018

Orientadores: Marcos Akira d'Ávila, Cecília Amélia de Carvalho Zavaglia / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecânica / Made available in DSpace on 2018-08-18T04:11:15Z (GMT). No. of bitstreams: 1 Ramos_SergioLopesFernandes_M.pdf: 1999649 bytes, checksum: 3668df0532fba5829156d8937f7ba8be (MD5) Previous issue date: 2011 / Resumo: O uso e pesquisa do polímero Policaprolactona (PCL) como biomaterial vem sendo amplamente difundido nas últimas décadas. Sua capacidade de interagir com o organismo, propriedades mecânicas e capacidade de reabsorção são as principais características que levaram a escolha deste material para o desenvolvimento de uma estrutura que aja como suporte celular para uso em Engenharia Tecidual. Neste trabalho, o objetivo foi produzir e caracterizar membranas de PCL obtidas pelo processo de eletrofiação ou "electrospinning". Este processo, que utiliza uma diferença de potencial para extrair "fios" a partir de uma solução polimérica eletricamente carregada, é relativamente novo e versátil, sendo capaz de produzir redes macrométricas a partir de um emaranhado de "fios" que variam de diâmetros nano até micrométricos. As amostras foram devidamente analisadas e caracterizadas utilizando Microscopia Eletrônica de Varredura (MEV), Calorimetria Diferencial de Varredura (DSC), Termogravimetria (TG), Infravermelho por Transformada de Fourrier (FTIR), Análise Dinâmico Mecânica (DMA) e ensaio in vitro com células tronco mesenquimais de tecido adiposo (MSCs). As membranas exibiram propriedade de biocompatibilidade, o que levou à crer que a porção de solvente utilizada para fabricação dos fios foi eliminada, possibilitando adesão, penetração e proliferação celular através da estrutura / Abstract: The Policaprolactone polymer has been widely investigated as cellular support for tissue engineering purposes. Its biocompatibility, adequate mechanical properties and resorption capability are the main aspects that has led to the choice of this material for a possible use as tissue engineering scaffolds. In this work, the objective was to prepare and characterize PCL non-woven fibrous networks obtained through the electrospinning process. This process, which uses electrical potential in order to extract fibers from a electrically charged polymer solution is relatively new and versatile, being capable to produce a macroscopic structure composed of non-woven networks of fibers varying from the nanoscale to the microscale range. The samples were characterized using Scanning Electron Microscopy (SEM), Scanning Differential Calorimetry (DSC), Thermogravimetry (TG), Infrared Fourrier Transform (FTIR), Dynamic Mechanical Analysis (DMA) and in vitro tests with Mesenquimal Stem Cells (MSCs). The membranes were considered biocompatible, which led to believe that the solvent portion was eliminated during the process, enabling adhesion, penetration and cellular proliferation within the structure / Mestrado / Materiais e Processos de Fabricação / Mestre em Engenharia Mecânica

Engenharia tecidual

Poli (caprolactona)

Biomateriais

Tissue engineering

Polycaprolactone

Biomaterials

Surface chemical modification of PCL films for peripheral nerve repair

De Luca, Alba Carla

January 2012

Nerve injury is a very common trauma affecting 300,000 people in Europe every year. Although autografts are currently the gold standard in surgery, they can cause loss of sensation and scar tissue formation. Artificial nerve conduits are a valid alternative for peripheral nerve repair. They can provide a confined environment during the regeneration process, enabling axons sprouting from the proximal to the distal nerve segments as well as reducing scar tissue formation. Poly-e-caprolactone (PCL) is a biocompatible and biodegradable polymer suitable for the fabrication of nerve guidances. In particular, previous works demonstrated that neural cells are able to adhere and proliferate on micropitted PCL films obtained through solvent casting. Also, short term studies showed that axons were able to bridge 1cm injury gap. In this work a 18 weeks long term in vivo experiment using a rat model was performed to investigate the reinnervation of end organ skin and muscle. PCL conduits were compared to autografts, with no significant differences in terms of regeneration and reinnervation. However, Schwann cells (SCs), the most important glial cells in the peripheral nervous system, showed poor attachment in vitro on PCL scaffolds; hence, surface modification was carried out in order to improve the material biocompatibility. The effect of both hydrophilicity and functional groups on SCs was first investigated. PCL films were then hydrolysed and aminolysed to modify the surface with carboxylic and amino groups respectively. Hydrolysed films increased remarkably the surface hydrophilicity, although topography and mechanical properties were not affected. Conversely, the tensile modulus and strength were significantly reduced by aminolysis, but still suitable for the desired application. The two treatments influenced also the morphology of SCs. It was demonstrated that cell elongation was induced by hydrophilic surfaces, whilst cells preferred cell-cell interaction when cultured on aminolysed films. However, cell proliferation was remarkably increased on the latter surfaces, confirming previous results obtained on substrates characterised by amino groups. These results confirmed that a good balance between hydophilicity and surface chemistry is necessary to guarantee the best cell response. In order to enhance both proliferation and morphology of SCs, arg-gly-asp (RGD) sequences were immobilised on the PCL film surface using two different reaction mechanisms. Carbodiimide chemistry was compared to a new mechanism developed in the present study based on the Thiol chemistry. Biological tests performed on these modified films demonstrated the improvement of SC response after the peptide immobilisation using the novel approach. Cell attachment and proliferation were three times higher compared to untreated PCL films. It was also observed that the presence of peptides on the film surface induced the formation of focal adhesion plaques by SCs, important for the perception of cellular signals when in contact with a particular substrate. Hence, a good balance between focal adhesion and adhesion forces was achieved after peptide immobilisation. Overall the results of this study showed that material functionalisation is very important for SC response and it will be fundamental for the production of artificial nerve conduits.

617.4

Development of Bio-environmentally Compatible Implant Materials by the Function of Precursors of Apatite / アパタイト前駆体機能による生体環境調和インプラント材料の開発

Hasnat, Zamin

23 September 2020

京都大学 / 0048 / 新制・課程博士 / 博士(エネルギー科学) / 甲第22796号 / エネ博第410号 / 新制||エネ||78(附属図書館) / 京都大学大学院エネルギー科学研究科エネルギー基礎科学専攻 / (主査)教授 坂口 浩司, 教授 佐川 尚, 准教授 高井 茂臣 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DFAM

Bioactivity

Precursors of Apatite

Hydroxyapatite

Zirconia

Polyvinylidene fluoride

Polycaprolactone

501

Polykaprolakton, jeho syntéza, charakterizace a degradabilita / Polycaprolactone, synthesis, characterization, and degradability

Boháčová, Zdeňka

January 2010

Presented diploma thesis deals with the study of ring-opening polymerization (ROP) of caprolactone catalyzed by novel organic and organometallic compounds. In the theoretical part of the thesis a summary of polymerization strategies and catalytic/initiators systems for ROP of polyesters is overviewed on the basis of reported background research. In experimental part a series of caprolactone polymerization runs with the view of polymerization conditions (solution/monomer ratio, catalyst/initiator ratio, monomer/initiator ratio and monomer concentration) at the temperature range of 25-70 °C was carried out. The experimental study was focused on catalytic precursors based on organic carbenes (tBuNCH=CHN+tBu)CH Cl- (NHC-tBu) in tetrahydrofuran solution and complex of aluminium{O,O’-[4,5-P(O)Ph2tz]-AlMe2} Ph = phenyl, tz = triazole, (OAlMe2) in chlorobenzene solution. Obtained polymers were precisely characterized by means of 1H NMR spectroscopy (Bruker Avance), Differential scanning calorimetry (TA Instruments Q 2000) and Gel permeation chromatography (Agilent Technologies 1100 series) methods. The microbial degradability of synthesized polymer sample having Mn = 12 kg/mol, Mw/Mn = 2.5 and crystallinity degree of 53 % was examined. The polymer in the form of melt-pressed films and powder form was bacterially aged in Bacillus subtilis (BS) strain inoculated mineral and nutrient media for 42 days. Scanning electron microscopy (SEM) and Confocal laser scanning microscopy (CLSM) confirmed the crack development on the surface of films as the consequence of microbial attack in comparison with unchanged control samples. Moreover, the pink coloration of polymer suspension was observed as the consequence of bacterial activity.

Electrospun polycaprolactone scaffolds under strain and their application in cartilage tissue engineering

Nam, Jin

22 September 2006

No description available.

Engineering, Materials Science

Tissue Engineering

Electrospinning

Polycaprolactone

Articular cartilage

Improved cell infiltration of electrospun nanofiber mats for layered tissue constructs

Mahjour, S.B., Sefat, Farshid, Polunin, Y., Wang, L., Wang, H.

04 February 2016

Yes / While achieving the spatial organization of cells within 3D assembled nanofiber/cell constructs via nanofiber-enabled cell layering, the small sizes of inter-fiber pores of the electrospun nanofiber mats could significantly limit cell penetration across the layers for rapid formation of an integrated tissue construct. To address this challenge, efforts were made to improve cell-infiltration of electrospun nanofiber mats by modulating the density distribution and spatial organization of the fibers during electrospinning. Collection of collagen-containing electrospun nanofibers (300–600 nm in diameter) onto the surface of a stainless steel metal mesh (1 mm × 1 mm in mesh size) led to the periodic alternation of fiber density from densely packed to loosely arranged distribution within the same mat, in which the densely packed fibers maintained the structural integrity while the region of loose fibers allowed for cell penetration. Along with improved cell infiltration, the distinct fiber organization between dense and loose fiber regions also induced different morphology of fibroblasts (stellate vs. elongated spindle-like). Assembly of cell-seeded nanofiber sheets into 3D constructs with such periodically organized nanofiber mats further demonstrated their advantages in improving cell penetration across layers in comparison to either random or aligned nanofiber mats. Taken together, modulation of nanofiber density to enlarge the pore size is effective to improve cell infiltration through electrospun mats for better tissue formation. / NSF-IIP. Grant Numbers: 1338958, 1346430; NSF-DMR. Grant Number: 1508511; NSF-CBET. Grant Number: 1033742; and NIAMS. Grant Number: 1R21 AR056416

Effects of Therapeutic Radiation on Polymeric Scaffolds

Cooke, Shelley L.

16 January 2014

High levels of ionizing radiation are known to cause degradation and/or cross-linking in polymers. Lower levels of ionizing radiation, such as x-rays, are commonly used in the treatment of cancers. Material characterization has not been fully explored for polymeric materials exposed to therapeutic radiation levels. This study investigated the effects of therapeutic radiation on three porous scaffolds: polycaprolactone (PCL), polyurethane (PU) and gelatin. Porous scaffolds were fabricated using solvent casting and/or salt leaching techniques. Scaffolds were placed in phosphate buffered saline (PBS) and exposed to a typical cancer radiotherapy schedule. A total dose of 50 Gy was broken into 25 dosages over a three-month period. PBS was collected over time and tested for polymer degradation through high performance liquid chromatography (HPLC) and bicinchoninic acid (BCA) protein assay. Scaffolds were characterized by changes in microstructure using Scanning Electron Microscopy (SEM), and crystallization using Differential Scanning Calorimetry (DSC). Additionally, gelatin ε-amine content was analyzed using Trinitrobenzene Sulfonic Acid Assay (TNBSA). Gelatin scaffolds immersed in PBS for three months without radiation served as a control. Each scaffold responded differently to radiation. PCL showed no change in molecular weight or microstructure. However, the degree of crystallinity decreased 32% from the non-irradiated control. PU displayed both changes in microstructure and a decrease in crystallinity (85.15%). Gelatin scaffolds responded the most dramatically to radiotherapy. Samples were observed to swell, yet maintain shape after exposure. As gelatin was considered a tissue equivalent, further studies on tissues are needed to better understand the effects of radiotherapy. / Master of Science

radiation aging

gelatin

polycaprolactone

polyurethane

porous scaffolds

tissue engineering

Copolymères à base de polycaprolactones greffées par des chitooligosaccharides : vers des nanogels bioactifs et biostimulables / Chitooligosaccharide grafted polycaprolactone copolymers : toward bioactive and biocompatible nanogels : toward bioactive and biocompatible nanogels

Guerry, Alexandre

30 November 2012

Actuellement, la mise au point de systèmes de vectorisation d'agents chimio-thérapeutiques performants fait l'objet d'une intense recherche. Les nanoparticules en particulier sont étudiées, car elles permettent de solubiliser des molécules hydrophobes en milieux aqueux tout en diminuant leur toxicité et leur dégradation. Toutefois, le devenir à long terme des nanoparticules est un paramètre important qu'il faut considérer dans la conception de ces nanovecteurs. Pour cette raison, le développement de nanoparticules auto-assemblées constituées de copolymères à bloc entièrement biocompatibles, biodégradables et aux propriétés de libération contrôlée est recommandé. Dans cette perspective, nous avons étudié les propriétés d'auto-organisation de copolymères greffés amphiphiles de type chitooligosaccharide-grafted-polycaprolactone. Le premier chapitre révèle l'utilisation de l'aniline et de son dérivé alcyne comme un outil efficace pour l'amination réductrice de chitooligosaccharides. Dans le second chapitre, différentes familles de polycaprolactone avec des fonctions azide latérales sont décrites. Le troisième chapitre traite du couplage par chimie « click » de chaque bloc ainsi que de la caractérisation physico-chimique des nanoparticules en solution aqueuse. La réticulation de ses particules a permis d'obtenir les nanogels finaux. Pour conclure, des tests d'encapsulation et de libération contrôlée de la Doxorubicine (avec ou sans ajout de glutathion) ont été effectués / Currently, the development of efficient drug delivery systems has a great attention. Nanoparticles are particularly studied for their capacity to solubilise hydrophobic drugs in aqueous media and to decrease their toxicity and degradability. However, long term compatibility has to be considered in the conception of this nanocarrier. For this reasons, the development of self-assembled particles constituted of biocompatible, biodegradable block copolymers is highly recommended. In this perspective, we have studied the self-assembled properties of chitooligosaccharide-grafted-polycaprolactone copolymers. The first chapter reveals aniline catalysis and its alkyne derivative as an efficient way for reductive amination of chitooligosaccharides. The second chapter describes the synthesis of different polycaprolactones with pendant azide groups. The third chapter is dedicated to the grafting of each bloc performed by “click” chemistry as well as the formation and characterisation of nanoparticle conducted in aqueous media. These nanoparticles were cross-linked to form reduction-sensitive final nanogels. At last, entrapment and controlled Doxorubicine release (with or without glutathione) were explored.

Chitooligosaccharide

Polycaprolactone

Nanogels

Amination reductrice

Copolymères greffés

Vectorisation

Chitooligosaccharide

Polycaprolactone

Nanogel

Reductive amination

Grafted copolymers

Controlled drug release