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Size Exclusion PEGylation Reaction Chromatography ModellingKapadi, Ajith Nayak January 2006 (has links)
Size exclusion PEGylation reaction chromatography was investigated using a model developed by Fee (2005). Column dispersion was neglected and the PEGylation reaction was modelled as second order. The model allowed up to four PEG groups to be attached to a protein and accounted for succinic acid hydrolysis from activated PEG. The model was adapted to simulate a-lactalbumin PEGylation and succinic acid hydrolysis from activated PEG in a batch stirred tank so rate parameters from stirred tank kinetic experiments could be obtained and the model verified. The model was solved using finite differences and simulations run in Matlab. The effect of reaction parameters such as timing, length and concentration of PEG and protein injection, reaction rates, and model resolution on model simulation results was explored. In the size exclusion PEGylation simulations it was found that increasing protein concentration increased MonoPEG concentrations and increased the ratio of MonoPEG to starting protein feed concentration. Increasing PEG pulse length and starting PEG concentration initially increased MonoPEG concentration and product ratio until all protein had been PEGylated at which point MonoPEG concentration the product ratio levelled out. Increasing PEG hydrolysis rates did not affect the amount of MonoPEG produced but reduced the activated PEG concentration and increased succinic acid concentration. Optimal conditions for producing MonoPEG were found to be equal concentrations of PEG and protein, with the PEG injection length twice as long as the protein injection, and the PEG injection done immediately after the protein injection.
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Bone Targeting Salmon Calcitonin Analogues as Drug Delivery Systems for Bone DiseaseBhandari, Krishna H Unknown Date
No description available.
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Competitive IgG Adsorption on Protein A Chromatography Resins and Improving Resin Performance with PEGylated LigandsWeinberg, Justin B. 01 December 2017 (has links)
Protein A (ProA) chromatography is a bioseparations technique employed throughout the biopharmaceutical industry for the selective capture and purification of IgG-class monoclonal antibodies (mAbs) and Fc-fusion proteins. The rapid growth of mAbs as commercial therapeutics has motivated the need for improved, efficient, and high-throughput purification processes during manufacturing. In direct response, the work presented in thesis aims to 1) increase the scientific community’s understanding of IgG adsorption behavior on ProA chromatography resins and 2) improve the performance of ProA chromatography with ligands that are chemically modified using polyethylene glycol (PEGylated). The results of this thesis suggest that IgG molecules of varying binding strength, or varying elution pH, are capable of competing for binding sites on ProA chromatography resins in simultaneous or sequential adsorption. The competitive phenomenon derives from variance in IgG binding strength, or IgG elution pH, due to differences in sub-class behavior as well as secondary IgG binding interactions with the ProA ligand. Competition is readily apparent in the adsorption of human polyclonal IgG, which has a wide variety of IgG sub-classes and binding epitopes. Additionally, the results presented in this thesis suggest that ProA chromatography resins with PEGylated ligands are a viable path to increase resin robustness and real-world chromatographic selectivity. It is demonstrated that ligand PEGylation can increase resistance to proteolytic digestion, mitigate impurity interactions with mAbs that are bound to ProA, and increase process selectivity against Chinese Hamster Ovary host cell proteins by up to 37%. However, resins with large volumes of conjugated PEG significantly decrease IgG static binding capacity and decrease the available pore space for diffusion, resulting in losses in dynamic binding capacity and productivity. Lighter modifications appear to avoid losses in dynamic binding capacity, however, they do not appear to be effective at mitigating impurity interactions with mAbs that are bound to ProA, which is key to increasing process selectivity. PEGylation of ProA also universally increases the elution pH of IgG molecules by weakening the binding interaction. This last result opens another path of viability for PEGylated ProA ligands for purification of mAbs of Fc-fusion proteins that are sensitive to low pH environments.
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Adressage de Nanomédicaments à base de squalène / Targeted squalene-based nanomedicinesBui, Duc Trung 23 December 2013 (has links)
Les nanoparticules de Gemcitabine-Squalène (Gem-Sq), synthétisées suivant le concept de « squalénisation », ont montré des activités anticancéreuses très supérieures à celles obtenues en présence de Gem libre. Néanmoins, leur PEGylation, c’est-à-dire leur décoration par du poly(éthylène glycol)-squalène (PEG-Sq) pour augmenter leur temps de demi-vie plasmatique, s’est avérée infructueuse du fait d’une déstructuration colloïdale. Par ailleurs, aucune stratégie de fonctionnalisation pour effectuer un ciblage actif de cellules cancéreuses, n’est à ce jour disponible. Au cours de cette thèse, nous avons donc cherché à résoudre ces problèmes. Après une étude bibliographique portant sur la conception de nanoparticules de prodrogues lipidiques, dans le but d’établir un constat récent de l’état de l’art dans ce domaine, nous avons proposé une voie de synthèse pour obtenir des nanoparticules multifonctionnelles (i.e., thérapeutique, fluorescentes et ciblées) à base de Gem-Sq, et ce par co-auto-assemblage des composés conjugués de Rhodamine-Sq, Gem-Sq et Biotin-Sq. Ces nanoparticules ont montré une internalisation plus importante dans les cellules cancéreuses et une meilleure efficacité thérapeutique que les nanoparticules de Gem-Sq non-fonctionnalisées. Dans un deuxième temps, nous avons apporté une solution au problème de la PEGylation des nanoparticules de Sq via la synthèse et l’utilisation de composés conjugués de type Gem-poly(méthacrylate de squalène). Ces prodrogues macromoléculaires ont été synthétisées par polymérisation radicalaire contrôlée et plus précisément par la technique RAFT. Les nanoparticules obtenues par auto-assemblage en solution aqueuse sont stables et présentent des activités anticancéreuses importantes sur différentes lignées cellulaires. Leur PEGylation par ajout de Sq-PEG durant la formulation s’est avérée possible et n’a pas conduit à une déstabilisation colloïdale. Enfin, j’ai participé à l’élaboration d’une nouvelle famille de nanoparticules de prodrogues macromoléculaires qui a consisté à faire croitre de courtes chaines de polyisoprène (PI) à partir de la Gem, donnant ainsi des conjugués de type Gem-PI, capables de s’auto-assembler sous la forme de nanoparticules avec une activité anticancéreuse in vitro et in vivo. / Gemcitabine-Squalene (Gem-Sq) nanoparticles have been synthesized from the “squalenoylation” approach and have shown superior anticancer activities compared to those obtained with free Gem. However, their PEGylation, that is their coating with poly(ethylene glycol)-squalene (PEG-Sq) in order to increase their circulation time, has been unsuccessful, leading to colloidal disassembly. In addition, to the best of our knowledge, there is not functionalization strategy yet available to perform active targeting against cancer. During this PhD thesis, we have been looking for solutions to tackle these two important problems. After a littérature survey about the design of lipidic prodrug nanoparticles, in order to establish a pretty accurate picture of the domain, we have reported a synthetic approach towards multifunctional Sq-based nanoparticles (i.e., therapeutic, fluorescent and targeted), through the co-self-assembly of the different Sq-based materials; that is Rhodamine-Sq, Gem-Sq and Biotin-Sq. These nanoparticles have demonstrated a greater internalization into cancer cells and a greater therapeutic effect than non-functionalized Gem-Sq nanoparticles. In the next step, we have provided a solution to the PEGylation issue by synthetizing Gem-poly(squalenoyl methacrylate) macromolecular prodrugs. These materials have been prepared by controlled/living radical polymerization and especially the RAFT technique. The resulting nanoparticles exhibited significant anticancer activities against various cancer cells and can be successfully PEGylated by the addition of Sq-PEG during their formulation. Eventually, I have participated to the design of a new family of macromolecular prodrugs obtained from the growing of short polyisoprene (PI) chains from Gem, leading to Gem-PI nanoparticles after self-assembly of Gem-PI. The nanoparticles led to significant anticancer activity both in vitro and in vivo.
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Cellular Encapsulation Techniques: Camouflaging Islet Cells from the Immune and Inflammatory Responses Associated with Islet TransplantationFinn, Kristina Kateri 01 January 2008 (has links)
Diabetes is a debilitating disease affecting millions of people worldwide. The transplantation of insulin-producing, pancreatic islet cells has been an extensively explored approach for the treatment of Type 1 Diabetes. However, the need for a multi-donor source, the strong host immune responses, and a life-long immunosuppressive therapy regimen limits the widespread applicability of islet transplantation. Encapsulation of islet cells within a semi-permeable biomaterial as a means to mask transplanted cells from the host has been shown to be a viable option for the protection of islets upon transplantation. Recent advancements, incorporating additional knowledge of biomaterials, have revitalized the field of islet encapsulation. This thesis work focused on both micro- and nano-scale encapsulation techniques. Initially, a novel, covalently linked alginate-poly(ethylene glycol) (PEG), termed XAlginate-PEG, microcapsule was evaluated, and was shown to exhibit superior stability over traditional ionically bound alginate microcapsules. The XAlginate-PEG capsules exhibited a 5-fold decrease in osmotic swelling than traditional alginate microcapsules, and remained completely intact upon chelation of ionic interactions. In addition, in vitro study of the novel polymer matrix showed high compatibility with mouse insulinoma cell lines, rat and human islets. Furthermore, no disruption in islet function was observed upon encapsulation. The second study of this thesis work focused on the nano-scale encapsulation of islets with a single layer PEG coating. A PEG polymer was grafted directly on the collagen matrix of the islet capsule to form a stable amide bond. PEGylation of the islet cells was shown to camouflage inflammatory agents, such as tissue factor (TF), present on the surface of the islet, while maintaining islet morphology and function. In summary, PEG dampened coagulation cascade activation, and concealed activated factor X (afX) generation under pro-inflammatory culture conditions. The present findings contribute to the field of cellular encapsulation, both in the fabrication of novel encapsulation techniques and the evaluation of nano-scale coatings. The future potential of this research includes the attenuation of immune responses to transplanted cells, elimination of continuous immunosuppression, and provide flexibility in cell source. Furthermore, the platforms evaluated in this thesis are generalized for all cell types, thereby permitting translation of techniques to alternative cellular therapies.
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Drug Eluting Hydrogels : Design, Synthesis and EvaluationAhrenstedt, Lage January 2012 (has links)
Hydrogels have successfully proved themselves useful for drug delivery applications and several delivery routes have been developed over the years. The particular interest in this work was to design, synthesise and evaluate in situ forming drug eluting hydrogels, which have the potential to ameliorate the healing of cardiovascular diseases. With this aim the anti-inflammatory and immunosuppressant drugs rapamycin (Ra) and dexamethasone (Dex) were made water soluble by conjugation with polyethylene glycol (PEG). Ra was attached pendant from the terminal of PEGs while Dex was incorporated into dendritic structures grown from PEGs. These conjugates were further crosslinked into hydrogels by either conjugate or thiol-ene addition. The gel degradation was tuned to take between 5 and 27 days by using gel building block combinations that induced either 2 or 4 hydrolytically labile bonds per crosslink or by varying the number of crosslinking sites of the building blocks. The use of thiol-ene addition prolonged the degradation time nearly seven folded compared to conjugate addition as a more stable crosslink was formed. Two different formulations for gelling via conjugate addition were used (acrylate-thiol or vinyl sulphone-thiol) to deliver Ra, which was carried by either a 4- or 2-armed PEG. The elution kinetic for the respective gel formulation was of zero order during 15 and 19 days of gel degradation. In addition, Ra was PEGylated via esters, with a distance of either one or two carbons to a nearby thio-ether functionality. The difference in ester conjugation resulted in a slight but significant change in drug-PEG conjugate stability, which was mirrored by the increased time to reach the half amount of total drug elution; from 9.3 to 10.2 days and from 5.1 to 9.7 days for the two gel formulations, respectively. Dexamethasone was incorporated via an ester into dendrons of first and second generation pending from 2- and 4-armed PEGs at loadings of 2, 4 or 6 Dex molecules per carrier molecule. The resulting elution kinetic was of zero order during degradation periods of 5-27 days. Released Dex still possessed biological activity as determined by an in vitro cell assay. The novelties in this thesis are: (A) slow release of rapamycin obtained by covalent incorporation into hydrogels, (B) the use of unique PEG-based dendrimers to incorporate dexamethasone into a hydrogel and (C) zero order sustained release of dexamethasone at physiological pH. / Hydrogeler har framgångsrikt visat sig användbara för att leverera läkemedel och ett flertal metoder har utvecklats de senaste 20 åren. Fokuset i den här avhandlingen ligger på att designa, framställa och utvärdera läkemedelsutsöndrande hydrogeler som spontanhärdar in situ, vilka har potential att förbättra läkningen efter kardiovaskulär sjukdom. Med det syftet gjordes de anti-inflammatoriska och immunsänkande läkemedlen rapamycin (Ra) och dexametason (Dex) vattenlösliga genom att konjugeras med polyetylenglygol (PEG). Ra fästes kovalent längst ut på PEGar medans Dex inkluderades i dendritiska strukturer vilka byggdes från ändpunkten av PEGar. De här konjugaten tvärbands till hydrogeler via antingen konjugerad addition eller radikal polymerisation. Nedbrytningen av gelerna trimmades till att ta mellan 5 och 27 dagar genom att använda kombinationer av gelbyggstenar som bildar antingen 2 eller 4 hydrolyserbara estrar per tvärbindning eller genom att variera antalet tvärbindningspunkter hos byggstenarna. Användandet av radikal polymerisation i sig ledde till att nedbrytningen av geler tog nära sju gånger längre tid jämfört med geler gjorda via konjugerad addition eftersom stabilare tvärbindningar då formas. Två olika kombinationer för härdning via konjugerad addition (akryl-tiol eller vinylsulfon-tiol) användes för att leverera Ra som bars av antingen en 4- eller 2-armad PEG. Utsöndringskinetiken av Ra för de två kombinationerna var av nollte ordningen under de 15 och 19 dagar som gelerna degraderade. Dessutom, Ra PEGylerades via estrar med ett avstånd på antingen ett eller två kol till en närliggande tioeter. Skillnaden i avstånd ledde till en liten men signifikant skillnad i stabiliteten hos Ra-PEG konjugaten, vilket speglades i den förlängda tiden att nå halva mängden av den totala läkemedelsutsöndringen; från 9.3 till 10.2 dagar och från 5.1 till 9.7 dagar för de två respektive gelkombinationerna. Dex kopplades in via en esterbindning till dendroner av första och andra generationen byggda från PEGar med 2 eller 4 armar, vilket resulterade i att 2, 4 eller 6 Dex levererades per bärarmolekyl. Dex eluerade med nollte ordningens kinetik under degraderingsperioder på mellan 5 och 27 dagar. Vidbehålllen biologisk aktivitet av eluerad Dex bekräftades genom cellexperiment in vitro. Nyheterna i den här avhandlingen består av: (A) kontrollerad utsöndring av rapamycin uppnådd genom kovalent inbindning till hydrogeler, (B) användandet av unika PEGbaserade dendrimerer för kovalent inbindning av dexametason till hydrogeler och (C) nollte ordningens utsöndring av dexametason vid fysiologiskt pH. / <p>QC 20130204</p>
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Criteria for Selecting PEGylation Sites on Proteins for Higher Thermodynamic StabilityLawrence, Paul B. 01 June 2016 (has links)
PEGylation of protein side-chains has been used for more than 30 years to enhance the pharmacokinetic properties of protein drugs, and has been enabled by the recent development of many chemoselective reactions for protein side-chain modification. However, there are no structure- or sequence-based guidelines for selecting sites that provide optimal PEG-based pharmacokinetic enhancement with minimal loss to biological activity. Chapter 1 is a brief introduction to protein PEGylation. In chapter 2 we use the WW domain of the human protein Pin 1 (WW) as a model system to probe the impact of PEG on protein conformational stability. Using a combination of experimental and theoretical approaches, we develop a structure-based method for predicting which sites within WW are most likely to experience PEG-based stabilization, and show that this method correctly predicts the location of a stabilizing PEGylation site within the chicken Src SH3 domain. PEG-based stabilization in WW is associated with enhanced resistance to proteolysis, is entropic in origin, and likely involves disruption by PEG of the network of hydrogen-bound solvent molecules that surround the protein. Chapter 3 shows that PEG-based stabilization of the WW domain depends strongly on the identity of the PEG-protein linker, with the most stabilizing linkers involving conjugation of PEG to an Asn side-chain amide nitrogen. Chapter 4 investigates the interplay between structure-based guidelines for PEG-base stabilization developed in chapter 2 and the different chemistries explored in chapter 3.
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Analysis of Methoxy-polyethylene Glycol-modified Human Serum AlbuminHouts, Frederick William 30 May 2006 (has links)
No description available.
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Structural Studies of Oligosaccharides Attached to Proteins Expressed in Different Organisms and PEGylation of a non-Glycosylated ProteinMotari, Edwin Mwamba 26 August 2010 (has links)
No description available.
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Desenvolvimento de L-asparaginase peguilada de E. chrysanthemi para o tratamento de leucemias / Development of pegylated E. chrysanthemi L-asparaginase for the treatment of leukemiasKarin Mariana Torres Obreque 04 August 2017 (has links)
A crisantaspase é uma enzima do tipo asparaginase (ASNase) produzida pela bactéria Erwinia chrysanthemi e utilizada como biofármaco no tratamento da leucemia linfoblástica aguda (LLA) em casos de hipersensibilidade à ASNase de E. coli. As principais desvantagens deste biofármaco são a curta meia-vida (10 horas) e imunogenicidade. Nesse sentido, sua forma peguilada (PEG-crisantaspase) não só reduziria o efeito imunogênico, como também melhoraria a meia-vida plasmática. Atualmente, somente a ASNase de E. coli está disponível comercialmente na forma peguilada e essa, por ter sido uma das primeiras proteínas a serem peguiladas, é resultado de um processo de peguilação aleatória em resíduos de lisina. Portanto, apresenta alto grau de polidispersão em relação à quantidade de cadeias de PEG ligadas à enzima. Nesse trabalho desenvolvemos um processo de obtenção de crisantaspase peguilada de maneira sítio-específica, no grupamento N-terminal (PEG-crisantaspase). A crisantaspase foi obtida de forma recombinante na cepa E. coli BL21, cultivada em agitador metabólico e biorreator, em meio Luria Bertani. A produtividade volumétrica no biorreator aumentou 37% em comparação com o agitador metabólico (460 e 335 U·L-1·h-1 respectivamente). A crisantaspase foi recuperada por choque osmótico e purificada por cromatografia de troca catiônica (coluna HiTrap SP FF, 5 mL, eluição em pH 7,5), apresentando atividade específica de 694 U·mg-1, fator de purificação de 31 e rendimento de 69%. A crisantaspase purificada foi peguilada com mPEG-NHS 10 kDa, em tampão fosfato 100 mM, 22 °C, razão molar enzima:PEG 1:50 durante 30 min e sob diferentes valores de pH (6,5-9,0). O melhor rendimento de peguilação N-terminal (50%) foi em pH 7,5 com menor formação de estruturas poli-peguiladas (7%). A PEG-crisantaspase foi isolada por cromatografia de exclusão molecular, retendo 50% da atividade específica (357 U·mg-1) com valor de kM três vezes maior do que o da crisantaspase (150 e 48,5 µM respectivamente). Entretanto, apresentou maior estabilidade em altas temperaturas. Em duas semanas, a crisantaspase perdeu 93% de sua atividade específica enquanto que a PEG-crisantaspase foi estável por 20 dias. Portanto, a enzima PEG-crisantaspase desenvolvida representa uma alternativa promissora para o tratamento da LLA. / Crisantaspase is an asparaginase enzyme (ASNase) produced by Erwinia chrysanthemi bacterium and used as biopharmaceutical in the treatment of acute lymphoblastic leukemia (ALL) in case of hypersensivity to E. coli ASNase. The main disadvantages of this biopharmaceutical are the short half-life (10 hours) and immunogenicity. In this sense, its PEGylated form (PEG-crisantaspase) could not only reduce the immunogenic effect but also improve plasma half-life. Currently, only E. coli ASNase is commercially available in its pegylated form. Since ASNase was one of the first proteins to be pegylated, it corresponds to a random PEGylation process on lysine residues and consequently preparations are highly polydisperse. In this work we developed a process to obtain a site-specific N-terminal PEGylated crisantaspase (PEG-crisantaspase). Crisantaspase was recombinantly expressed in E. coli BL21 strain, grown in shaker and bioreactor, in Luria Bertani medium. Volumetric productivity in bioreactor increased 37% compared to shaker conditions (460 and 335 U·L-1·h-1 respectively). Crisantaspase was extracted by osmotic shock and purified by cation exchange chromatography (HiTrap SP FF column, 5 mL, elution at pH 7.5), presenting specific activity of 694 U·mg-1,31 purification fold and an yield of 69%. Purified crisantaspase was PEGylated with 10 kDa mPEG-NHS in 100mM phosphate buffer, 22°C, enzyme:PEG molar ratio of 1:50 for 30 min, and at different pH values (6.5-9.0). The highest N-terminal pegylation yield (50%) was at pH 7.5 with less poly-PEGylated forms (7%). PEG-crisantaspase was purified by size-exclusion chromatography, retaining 50% of specific activity (357 U·mg-1) with a kM value 3 times higher than crisantaspase (150 and 48,5 µM respectively). Nonetheless, PEG-crisantaspase was found to be more stable at high temperatures and over the time. In two weeks, crisantaspase lost 93% of its specific activity, while PEG-crisantaspase was stable for 20 days. Therefore, the novel PEG-crisantaspase enzyme developed represents a promising alternative for the treatment of ALL.
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