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411	Beiträge zur Entwicklung Wasser speichernder Materialien auf Basis von Stärke und Lignin Passauer, Lars 07 July 2008 (has links) Vor dem Hintergrund des weltweit wachsenden Bedarfes an Bodenverbesserungsmitteln, durch die Humus-, Nährstoff- und Wassermangel auf Problemstandorten kompensiert werden sollen, war es das Ziel der vorliegenden Arbeit, Bodenwasser-speicher auf Basis der nachwachsenden Biopolymere Stärke und Lignin zu entwickeln. Durch Derivatisierung der Stärke wurde deren Hydrophilie deutlich gesteigert, was Voraussetzung für die Bildung von Hydrogelen war. Es konnte gezeigt werden, dass durch Vernetzung der wasserlöslichen Stärkederivate Carboxymethylstärke und Monostärkemonophosphat mit Di-/Tricarbonsäuren quellfähige Hydrogele erzeugt werden, deren Quellungsvermögen und rheologische Eigenschaften über die Wahl des Vernetzers und die Vernetzerstoffmenge gezielt eingestellt werden können. Die Modifizierung von Lignin wurde durch Oxidation mit Wasserstoffperoxid, z.T. in Kombination mit Fe(II)- bzw. Mn(II)-Chloriden realisiert. Dadurch wurde die Vernetzbarkeit von Lignin deutlich verbessert, was auf oxidativ bedingte Strukturänderungen des Lignins zurückzuführen war. Diese bestanden im Wesentlichen in der Spaltung und Oxidation der Lignin-Seitenkette sowie der Hydroxylierung der Seitenkette und aromatischer Strukturen. Die Vernetzung von Lignin mit Poly-(ethylenglycol)-diglycidylether ergab quellfähige Hydrogele, deren Wasseraufnahmevermögen und rheologische Materialfunktionen von der eingesetzten Vernetzerstoffmenge abhängig sind. Es konnte gezeigt werden, dass durch den Einsatz von Stärkephosphat- und Lignin-Hydrogelen das Wasserspeichervermögen erhöht und die Evaporationsraten eines entsprechend behandelten Sandbodens verringert werden. Im Wachstumsversuch wurden die Frischmasseerträge von Gelbsenf (Sinapis alba) durch Behandlung eines Sandbodens mit Hydrogelen gesteigert. / Soil degradation leading to a lack of humus, nutrients and water especially on exploited sites causes the worldwide need in soil amendments. Aim of the work was the development of hydrogels from renewable biopolymers starch and lignin improving water retention especially in degraded soils. A significant increase of hydrophilic properties of starch was obtained by chemical modification with the objective of forming starch based hydrogels. Swellable hydrogels were formed by cross-linking of water soluble starch derivatives like carboxymethyl starch and monostarch monophosphates with di- and tricarboxylic acids. Swelling capacity and rheological properties of the starch gels were selective adjusted by variation of cross linking agent and whose amounts. Modification of lignin was realized by oxidation with hydrogen peroxide partly in combination with ferrous and manganese chlorides, respectively. In consequence of oxidative structural changes which were cleavage and oxidation of side chain as well as aliphatic and aromatic hydroxylation, gelation of lignin was improved significant. Lignin hydrogels with different swelling capacities and rheological functions were formed by cross-linking lignin with different amounts of poly (ethylene glycol) diglycidyl ether. Application of hydrogels based on starch and lignin causes increased water storing capacity/field capacity and decreased evaporation of a sandy soil as well as an increased biomass yield of yellow mustard (Sinapis alba). info:eu-repo/classification/ddc/630 ddc:630
412	Organicko-anorganické polymery - syntéza a charakterizace hybridních polymerů a nanokompozitů / Organic-inorganic polymers - synthesis and characterization of hybrid polymers and nanocomposites Depa, Katarzyna January 2017 (has links) In the first part of this work, silica nanoparticles and alternative or additional filler phases were incorporated into hydrogels based on the temperature-sensitive poly(N- isopropylacrylamide) (PNIPAm). Nano-SiO2-filled porous PNIPAm hydrogels with an enhanced force response (up to 100 g) to temperature stimuli were obtained by increasing several times the pore wall thickness, which was achieved via reducing the solvent (porogen) content during the gels' cryo-synthesis. A similar optimization of the force response was also carried out for analogous gels reinforced by nano-TiO2, in which the reinforcing effect of the filler is weaker. Partial intercalation of amylopectin starch into divinyl-crosslinked bulk as well as porous PNIPAm gels several times improved their extensibility. In case of starch-rich bulk gels, a very fast and extensive one-way deswelling in response to increased temperature was achieved (re-swelling upon cooling is much slower), which is attributed to specific properties of the starch-PNIPAm interface. In doubly-filled bulk PNIPAm/nano-SiO2/starch gels, a very strong synergic reinforcing effect of both fillers is observed, due to specific hydrogen bridging between the three phases. Highly porous cryogels based on PNIPAm/nano- SiO2/starch displayed a highly improved extensibility...
413	Active hydrogel composite membranes for the analysis of cell size distributions Ehrenhofer, Adrian, Wallmersperger, Thomas 26 March 2021 (has links) Active membranes with switchable pores that are based on hydrogels can be used to measure the cell size distribution in blood samples. The system investigated in the present research is based on a polyethylene terephthalate (PET) membrane that is surface polymerized with poly (N-isopropyl acrylamide) (PNiPAAm) to form active pores of arbitrary geometry. The PET membrane provides the functionality of a backbone for mechanical rigidity, while the soft PNiPAAm hydrogel forms the active pores. Modeling and simulation of the active hydrogel behavior proved to adequately predict the opening and closing of the pores under application of an activating stimulus, e.g. temperature. The applied model is called Temperature-Expansion-Model and uses the analogy of thermal expansion to model the volume swelling of hydrogels. The Normalized Extended Temperature-Expansion-Model can englobe arbitrary hydrogels and large geometric displacements. Studies of pore opening - performed by using commercial finite element tools - show good agreement of the experimentally measured shape change of active pores. Based on these studies, the particulate fluid flow through the switchable pores is analyzed. Through application of a membrane process, i.e. a given variation of applied pressure and switching stimulus for the hydrogel, the size profile of the blocking particles can be measured directly using the flux difference under constant pressure. This allows the measurement of the cell size distribution in blood samples, e.g. to detect circulating tumor cells or anomalies in the distribution that hint to anemia. info:eu-repo/classification/ddc/620 ddc:620
414	Window-opener as an example for environment measurement and combined actuation of smart hydrogels Ehrenhofer, Adrian, Elstner, Martin, Filippatos, Angelos, Gude, Maik, Wallmersperger, Thomas 03 May 2021 (has links) An environment is defined by a set of field values, such as temperature, electro-magnetic field, light intensity, air humidity and air composition. Smart materials, such as hydrogels, are able to react to these kinds of stimuli. The spatial and time development of environmental values is governed by transport equations. Hence the reaction, i.e. actuation or sensing, of the smart material can be described based on the same assumptions. The displacement, here swelling and deswelling, of the material depends on the combination of the environmental parameters. Smart materials are called multi-sensitive, when more than one parameter is purposely used (i) to manipulate the material, i.e. as an actuator or (ii) to measure the quantities, i.e. as a (multi-)sensor. However, the material can also perform (iii) the objective of a logic processing unit in addition to (i) and (ii). In the current work, we present a device that realizes this concept: An automatic window opener that senses environmental parameters (light-level and air temperature) and reacts accordingly. The hydrogel material that is included in the simplistic device simultaneously acts as sensor, logic processing unit and actuator. info:eu-repo/classification/ddc/620 ddc:620
415	Hydrogels for engineering Ehrenhofer, Adrian, Wallmersperger, Thomas 09 August 2019 (has links) In engineering, materials are chosen from databases: Engineers orient on specific parameters such as Young's modulus, yield stress or thermal expansion coefficients for a desired application. For hydrogels, the choice of materials is rather tedious since no generalized material parameters are currently available to quantify the swelling behavior. The normalization of swelling, which we present in the current work, allows an easy comparison of different hydrogel materials. Thus, for a specific application like a sensor or an actuator, an adequate material can be chosen. In the current work, we present the process of normalization and provide a course of action for the data analysis. Special challenges for hydrogels like hysteresis, conditional multi-sensitivity and anisotropic swelling are addressed. Then, the Temperature Expansion Model is shortly described and applied. Using the derived normalized swelling curves, a nonlinear expansion coefficient β(F) is derived. The derived material behavior is used in an analytical model to predict the bending behavior of a beam made of thermo-responsive hydrogel material under an anisotropic temperature load. A bending behavior of the beam can be observed and the impact of other geometry and material parameters can be investigated. To overcome the limitations of the one-dimensional beam theory, the material behavior and geometry can be implemented in Finite Element analysis tools. Thus, novel applications for hydrogels in various fields can be envisioned, designed and tested. This can lead to a wider use of smart materials in sensor or actuator devices even by engineers without chemical background. info:eu-repo/classification/ddc/620 ddc:620
416	Injectable hydrogels for innovative clinical applications / Hydrogels injectables pour applications cliniques innovants Alonci, Giuseppe 12 December 2018 (has links) Cette thèse porte sur la conception d'hydrogels injectables pouvant être utilisés en chirurgie mini-invasive, par exemple en dissection endoscopique sous-muqueuse (ESD) ou en réparation de hernie.Les polyamidoamines (PAAm) constituent une classe d'hydrogel intéressante à ces fins. Après avoir étudié les différents facteurs qui affectent leurs propriétés, nous montrons qu'il est également possible d'obtenir des microgels à base de PAAm pour la délivrance de médicaments ou l'encapsulation de cellules. Il est possible de synthétiser des PAAm dégradables qui peuvent être injectés dans la sous-muqueuse de l'estomac pour la ESD.Nous avons montré que les hydrogels hybrides alginate / PAAm peuvent être utilisés pour le traitement percutané de la hernie inguinale directe et des crèmes à base d'hydrogel ont été préparées pour être utilisées pour le colmatage des fistules. Le dernier chapitre de la thèse est consacré à la réticulation de l'acide hyaluronique pour la chirurgie esthétique. / This thesis deals with the design of injectable hydrogels that can be used in minimally invasive surgery, such as endoscopic submucosal dissection (ESD), percutaneous hernia repair or fistulas closure.Polyamidoamines (PAAm) constitute a class of hydrogel of special interest for these purposes. After studying the different factors that affect their properties, we show that it is also possible to obtain PAAM-based microgels for applications in drug delivery or cell encapsulation.It is possible to synthesize redox-responsive nanocomposite degradable PAAm that can be injected into the submucosa of the stomach to facilitate the ESD.We show that hybrid alginate/PAAm hydrogels can be used for the percutaneous treatment of direct inguinal hernia and hydrogel-based creams have been prepared for use in fistulas closure. The last chapter of the thesis is devoted to the development of a new crosslinking strategy for hyaluronic acid in cosmetic surgery. Hydrogels Endoscopique sous-muqueuse Chirurgie Biocompatibilité Polyamidoamines Ingénierie tissulaire Injectables Biomatériaux Hydrogel ESD Surgery Biocompatibility Poly(amidoamine)s Tissue engineering Injectable Biomaterials 541.34
417	Microfluidic Systems based on Chemical Volume-Phase-Transition Stimuli-Responsive Hydrogels Pini, Cesare 19 January 2019 (has links) Microfluidics is an expanding research field that lies at the interface of engineering, physics, chemistry and biology and offers promises in the development in a wide range of applications from point-of-care (POC) diagnostics to regenerative medicine, from drug testing to DNA sequencing. The number of publications in the field has been steadily growing in the last two decades and the trend does not show any sign of slowing down. On top of that, the market value generated by microfluidics is expected to quadruple in the time spam from 2013 to 2023: from 1.59 billion dollars in 2013, it is expected to grow to 8.64 billion dollars in 2023. There are however a series of limitations which prevent the full development of microfluidic technology. As it has already been pointed out in many publications in the last decade, the lack of a killer application capable of really making the difference out of the research labs and the academic playgrounds around the world is an impeding factor to the full-scale development of microfluidcs at an industrial level, also due to the lack of industrial standards. A number of authors, though, are of the opinion that the actual concept itself needs to challanged and that a complete re-thinking of the current technological platform should be done in order to make the breakthrough advance allowing a long-standing promising field to finally realise itself.In this work a completely new concept, based on volume-phase-transition smart-hydrogels, is presented and the foundations for a transistor-like technological platform are laid. A strong focus is therefore based on the basic element itself, i.e. volume-phase-transition smart-hydrogels, and on the possible ways that it might be integrated in microfluidic systems. Furthermore, basic circuits that lay the foundations for a logic system are presented together with other applications that replicate some elementary functions in microelectronics, such as oscillators. Finally, integration of logic gates as well as basic circuits is presented, in order to lay the foundations for chemical integrated microfluidic circuits. info:eu-repo/classification/ddc/620 ddc:620 info:eu-repo/classification/ddc/530 ddc:530
418	Modellierung und Simulation des Verhaltens von durchströmten schaltbaren Membranen Ehrenhofer, Adrian 25 April 2019 (has links) Die schaltbare Filtration mithilfe von Hydrogel'=Verbundmembranen zeigt großes Potential zur Lösung einer der grundlegenden Aufgaben in der Humanmedizin: der unkomplizierten und schnellen Analyse von Blutproben zur Erkennung von Unregelmäßigkeiten, wie zum Beispiel zirkulierenden Tumorzellen. In der vorliegenden Arbeit wird ein solches System diskutiert und mithilfe von Methoden des Maschinenwesens -- Modellierung und Simulation -- untersucht. Das betrachtete System besteht aus einer aktiven Hydrogelschicht, welche auf einer passiven Polymerschicht aufgebracht ist und damit eine schaltbare Verbundmembran bildet. Die Arbeit folgt zwei Hauptpfaden: Im festkörpermechanischen Teil werden die mechanischen Aspekte von Verbundmembranen dargestellt, während im fluidmechanischen Teil die Permittivität und Selektivität von Membranen näher beleuchtet werden. Im Folgenden werden Modelle zur Schaltbarkeit ausgehend von aus der Literatur bekannten Ansätzen entwickelt. Diese werden dann im Rahmen von Simulationen -- sowohl im kommerziellen Finite-Elemente-Programm Abaqus, als auch in selbst geschriebenen Matlab-Codes -- umgesetzt. Die vorliegende Arbeit zeigt, dass ein schaltbares System zur Analyse von Zellgrößenprofilen realisierbar und durch Modellierung und Simulation in einem Maß beschreibbar ist, sodass der experimentellen Realisierung nichts mehr im Wege steht. / Switchable filtration with hydrogel composite membranes shows great potential to solve one of the basic challenges in life sciences: the fast and easy analysis of blood samples to detect abnormal cells like e.g. circulating tumor cells. In the present work, a system providing these features is discussed using tools provided by engineering: modeling and simulation. The system consists of an active hydrogel composite membrane in combination with a passive polymeric membrane that provides mechanical stability. This forms a switchable composite membrane. The work follows two main paths: In the solid mechanics path, the composition of membranes and their mechanical aspects are discussed. The fluid mechanics path focuses on permittivity and selectivity for particle flows. Originating from the basic concepts of membrane permeation in literature, models for switchability are developed and simulations -- both in the commercial finite-element tool Abaqus and in Matlab scripts -- are performed. The present work proves that the concept of cell-size detection with switchable membranes is suitable for the task. Through the performed simulations, the corresponding processes can be described and designed so that the microfluidic analysis system can be experimentally realized. info:eu-repo/classification/ddc/620 ddc:620
419	The effect of PEO homopolymers on the behaviours and structural evolution of Pluronic F127 Smart Hydrogels for Controlled Drug Delivery Systems Shriky, Banah, Mahmoudi, N., Kelly, Adrian L., Isreb, Mohammad, Gough, Timothy D. 06 April 2022 (has links) Yes / Understanding the structure-property relationships of drug delivery system (DDS) components is critical for their development and the prediction of bodily performance. This study investigates the effects of introducing polyethylene oxide (PEO) homopolymers, over a wide range of molecular weights, into Pluronic injectable smart hydrogel formulations. These smart DDSs promise to enhance patient compliance, reduce adverse effects and dosing frequency. Pharmaceutically, Pluronic systems are attractive due to their unique sol-gel phase transition in the body, biocompatibility, safety and ease of injectability as solutions before transforming into gel matrices at body temperature. This paper presents a systematic and comprehensive evaluation of gelation and the interplay of microscopic and macroscopic properties under both equilibrium and non-equilibrium conditions in controlled environments, as measured by rheology in conjunction with time-resolved Small Angle Neutron Scattering (SANS). The non-equilibrium conditions investigated in this work offer a better understanding of the two polymeric systems’ complex interactions affecting the matrix thermo-rheological behaviour and structure and therefore the future release of an active pharmaceutical ingredient from the injectable DDS. Thermosensitive gel Thermal properties Rheological properties Small Angle Neutron Scattering (SANS) Drug release Colloidal crystals Drug delivery systems (DDS) Injectables Polyethylene glycol (PEG) Polyethylene oxide (PEO) Smart hydrogels
420	Fabrication Characterisation and Optimisation of Electrospun Scaffolds for Ligament Tissue Reconstruction. The Development of an Anterior Cruciate Ligament (ACL) Analogue using Electrospun PCL, PVA Hydrogel and Polyester Sutures Agbabiaka, Oluwadamilola A. January 2022 (has links) Year 2019, football, rugby, netball and skiing had most occurring ACL injuries, listed by United Kingdom National Ligament Report (NLR). The standard procedure treatment of complete laceration of the ACL, is performed by tissue autograft implantation designed from a patellar tendon, for replacement of damaged tissue using orthopaedic surgery. The aim of this thesis is to design and fabricate an ACL graft, attempting to mimic the natural ACL, for the purpose of tissue reconstruction. The desired graft analogues exhibited properties imitating native connective tissue, reducing pain through drug delivery with great biocompatibility and enhance suture mechanical strength. Various biomaterials were implemented into this study, utilising strategies; polymer solution fabrication, electrospinning, hydrogel synthesis, mechanical braiding and graft assembly to fabricate an ACL graft. The polymeric material poly (E- caprolactone) (PCL) was researched, utilising its ability to fabricate scaffolds. Results showed, three analogue ACL grafts (Braided PCL-BP, Braided PCL + Hydrogel-BPH & Braided PCL + Sutures-BPS) created utilising the properties of braiding, hydrogels and sutures, ultimately improving the versatility of electrospinning for tissue engineering and reconstruction. Graft analogues were tested and compared against patellar tendons producing similar tensile properties. Poly vinyl alcohol (PVA) hydrogels successfully held ibuprofen, revealing drug delivery characteristics, polyester threads improved mechanical properties of electrospun grafts and dry degradation showed that PCL did not lose significant mass over two months. Conclusion, tensile strength of patella tendon was 395x, 790x & 56x of analogue grafts (BP, BPH & BPS) respectively, having potential for improvement of tensile parameters for ligament reconstruction. Polycaprolactone (PCL) Electrospinning Grafts Hydrogel synthesis Fabrication Electrospun scaffolds Anterior Cruciate Ligament (ACL) Poly vinyl alcohol (PVA) hydrogels Polyester sutures Mechanical tensile test

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