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Gliadin degradation in vitro and in vivo by Rothia aeria bacteria and pharmaceutically modified subtilisin-A enzymeDarwish, Ghassan M. 13 July 2018 (has links)
INTRODUCTION: Foods enter the oral cavity and mix with saliva. Some foods are not well tolerated, for instance, gluten proteins in individuals suffering from celiac disease (CD). Celiac disease is a chronic immune-mediated inflammation of the duodenum, triggered by gliadin component of gluten contained in wheat, barley and rye. In previous studies we showed that oral Rothia bacteria can degrade gliadin in vitro. The objective of this study was to gain more insights into the role of Rothia bacteria and subtilisin-A enzyme on gliadin digestion in vivo, with the ultimate goal to find new therapeutic options for CD.
MATERIALS AND METHODS: Part I: Rothia bacterial proteins were analyzed for enzyme activity and subjected to LC-ESI-MS/MS. For in vivo, mice chow was prepared with and without R. aeria. Gliadin epitope abolishment was assessed in the mice stomach contents (n=9/group) by ELISA. Part II: Subtilisin-A was dissolved in various solutions, temperatures and incubation time to assess enzyme activity by using enzyme substrate (Suc-AAPF-pNA). Part III: PEGylation of subtilisin-A (Sub-A) was performed by mixing Sub-A with methoxy-polyethylene glycol (mPEG) and further encapsulated by polylactic-glycolic acid (PLGA). The activity of the modified enzyme to detoxify the immunogenic gliadin epitopes was evaluated at pH3.0.
RESULTS: Part I: R. aeria gliadin-degrading enzyme was found to be a member of the subtilisin family. In vivo, gliadins immunogenic epitopes were reduced by 32.6%. Part II: Sub-A dissolved at pH1.5 showed a band of 27kDa, while it only showed bands below 10kDa when dissolved at pH7.0, suggesting auto-proteolysis. The enzyme activity was completely lost at temperatures exceeding 60°C and also reduced 4-fold after 6hr incubation at 37°C. Part III: PEGylation protected Sub-A from autolysis. The microencapsulated Sub-A-mPEG-PLGA showed significantly increased protection against acid exposure in vitro. In vivo, gliadin immunogenic epitopes were decreased by 60% in the stomach of the mice fed with chow containing Sub-A-mPEG-PLGA.
CONCLUSION: The results provide proof for the contribution of oral Rothia bacteria to gliadin digestion and pharmaceutical modification can protect Sub-A from auto-digestion as well as from acidic insults, thus rendering the usefulness of coated subtilisins as a digestive aid for gluten degradation. / 2019-01-13T00:00:00Z
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Obten??o de sistemas multiparticulados de isoniazida revestidos com pol?mero de libera??o ent?ricaFreire, F?tima Duarte 21 September 2009 (has links)
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Previous issue date: 2009-09-21 / Known for thousands of years, tuberculosis (TB) is the leading cause of mortality by a single infectious disease due to lack of patient adherence to available treatment regimens, the rising of multidrug resistant strains of TB (MDR-TB) and co-infection with HIV virus. Isoniazid and rifampicin are the most powerful bactericidal agents against M. tuberculosis. Because of that, this couple of drugs becomes unanimity in anti-TB treatment around the world. However, the rifampicin in acidic conditions in the stomach can be degraded rapidly, especially in the presence of isoniazid, which reduces the amount of available drug for absorption, as well as its bioavailability, contributing to the growing resistance to tuberculostatic drugs. Rifampicin is well absorbed in the stomach because of its high solubility between pH 1 and 2 and the gastric absorption of isoniazid is considered poor, therefore it is mostly intestinal. This work has as objective the development of gastro-resistant multiple-systems (granules and pellets) of isoniazid aiming to prevent the contact with rifampicin, with consequent degradation in acid stomach and modulate the release of isoniazid in the intestine. Granules of isoniazid were obtained by wet method using both alcoholic and aqueous solutions of PVP K-30 as aggregating and binder agent, at proportions of 5, 8 and 10%. The influence of the excipients (starch, cellulose or filler default) on the physical and technological properties of the granules was investigated. The pellets were produced by extrusionesferonization technique using isoniazid and microcrystalline cellulose MC 101 (at the proportion of 85:15) and aqueous solution of 1% Methocel as platelet. The pellets presented advantages over granular, such as: higher apparent density, smaller difference between apparent and compaction densities, smoother surface and, especially, smaller friability, and then were coated with an organic solution of Acrycoat L 100 ? in a fluidized bed. Different percentages of coating (15, 25 and 50%) were applied to the pellets which had their behavior evaluated in vitro by dissolution in acidic and basic medium. Rifampicin dissolution in the presence of uncoated and coated isoniazid pellets was evaluated too. The results indicate that the gastro resistance was only achieved with the greatest amount of coating and isoniazid is released successfully in basic step. The amount of rifampicin in the dissolution medium when the isoniazid pellets were not coated was lower than in the presence of enteric release pellets. Therefore, the polymer Acrycoat L 100 ? was efficient for coating with gastro-resistant function and can solve the problem of low bioavailability of rifampicin and help to reduce its dosage / Conhecida h? milhares de anos, a tuberculose (TB) ? a principal causa de mortalidade por uma ?nica doen?a infecciosa devido ? falta de ades?o dos pacientes aos esquemas terap?uticos dispon?veis, o aparecimento de cepas multiresistentes e a co-infec??o com o v?rus HIV. A isoniazida e a rifampicina possuem o maior poder bactericida frente ao M. tuberculosis, sendo por isso unanimidade no tratamento anti-TB em todo o mundo. No entanto, a rifampicina em condi??es ?cidas do est?mago degrada-se rapidamente, principalmente na presen?a da isoniazida, diminuindo a quantidade de f?rmaco dispon?vel para absor??o bem como a sua biodisponibilidade, contribuindo para a resist?ncia crescente aos f?rmacos tuberculost?ticos. A rifampicina ? bem absorvida no est?mago devido ? sua alta solubilidade entre pH 1 e 2 e a absor??o g?strica da isoniazida ? considerada pobre, sendo ent?o, majoritariamente intestinal. O presente trabalho teve como objetivo o desenvolvimento de sistemas multiparticulados (granulados e p?letes) de isoniazida gastrorresistentes visando evitar contato da rifampicina com isoniazida e conseq?ente degrada??o no meio ?cido estomacal bem como modular a libera??o da isoniazida no intestino. Granulados de isoniazida foram obtidos por via ?mida utilizando solu??o alco?lica e solu??o aquosa de PVP K-30 como agente agregante/aglutinante, nas propor??es 5, 8 e 10%. A influ?ncia do excipiente (amido, celulose ou aus?ncia de diluente) sobre as propriedades f?sicas e tecnol?gicas dos granulados foi investigada. Os p?letes foram produzidos pela t?cnica de extrus?o-esferoniza??o utilizando isoniazida e Celulose MC 101 (na propor??o 85:15) e solu??o aquosa de Methocel 1% como agregante. Os p?letes apresentaram vantagens em rela??o aos granulados, como: maior densidade aparente, menor diferen?a entre as densidades aparente e de compacta??o, superf?cie mais lisa e, principalmente, menor friabilidade, sendo ent?o revestidos com uma solu??o org?nica de Acrycoat L 100? em leito fluidizado. Diferentes percentuais de revestimento (15, 25 e 50%) foram aplicados aos p?letes, os quais tiveram seus comportamentos avaliados in vitro por dissolu??o em meio ?cido e b?sico. Em seguida, a dissolu??o da rifampicina em meio ?cido na presen?a da isoniazida em p?letes n?o revestidos e p?letes revestidos foi avaliada tamb?m. Os resultados indicam que a gastrorresist?ncia foi obtida somente com a maior quantidade de revestimento, sendo a isoniazida liberada com sucesso na etapa b?sica. A quantidade de rifampicina dissolvida quando associada a p?letes de isoniazida n?o revestidos foi menor do que a observada na presen?a de p?letes de libera??o ent?rica. O pol?mero Acrycoat L 100? mostrou-se eficiente para o recobrimento com a fun??o de gastrorresist?ncia, podendo resolver o problema da baixa biodisponibilidade da rifampicina assim como ajudar a diminuir a dosagem utilizada
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Development and evaluation of a solid oral dosage form for an artesunate and mefloquine drug combination / Abel Hermanus van der WattVan der Watt, Abel Hermanus January 2014 (has links)
Malaria affects about forty percent of the world’s population. Annually more than 1.5 million fatalities due to malaria occur and parasite resistance to existing antimalarial drugs such as mefloquine has already reached disturbingly high levels in South-East Asia and on the African continent. Consequently, there is a dire need for new drugs or formulations in the prophylaxis and treatment of malaria. Artesunate, an artemisinin derivative, represents a new category of antimalarials that is effective against drug-resistant Plasmodium falciparum strains and is of significance in the current antimalarial campaign. As formulating an ACT double fixed-dose combination is technically difficult, it is essential that fixed-dose combinations are shown to have satisfactory ingredient compatibility, stability, and dissolution rates similar to the separate oral dosage forms.
Since the general deployment of a combination of artesunate and mefloquine in 1994, the cure rate increased again to almost 100% from 1998 onwards, and there has been a sustained decline in the incidence of Plasmodium falciparum malaria in the experimental studies (Nosten et al., 2000:297; WHO, 2010:17). However, the successful formulation of a solid oral dosage form and fixed dosage combination of artesunate and mefloquine remains both a market opportunity and a challenge.
Artesunate and mefloquine both exhibited poor flow properties. Furthermore, different elimination half-lives, treatment dosages as well as solubility properties of artesunate and mefloquine required different formulation approaches. To substantiate the FDA’s pharmaceutical quality by design concept, the double fixed-dose combination of artesunate and mefloquine required strict preliminary formulation considerations regarding compatibility between excipients and between the APIs. Materials and process methods were only considered if theoretically and experimentally proved safe. Infrared absorption spectroscopy (IR) and X-ray powder diffraction (XRPD) data proved compatibility between ingredients and stability during the complete manufacturing process by a peak by peak correlation. Scanning Electron Micrographs (SEM) provided explanations for the inferior flow properties exhibited by the investigated APIs. Particle size analysis and SEM micrographs confirmed that the larger, rounder and more consistently sized particles of the granulated APIs contributed to improved flow under the specified testing conditions.
A compressible mixture containing 615 mg of the APIs in accordance with the WHO recommendation of 25 mg/kg of mefloquine taken in two or three divided dosages, and 4 mg/kg/day for 3 days of artesunate for uncomplicated falciparum malaria was developed. Mini-tablets of artesunate and mefloquine were compressed separately and successfully with the required therapeutic dosages and complied with pharmacopoeial standards. Preformulation studies eventually led to a formula for a double fixed-dose combination and with the specific aim of delaying the release of artesunate due to its short half-life.
A factorial design revealed the predominant factors contributing to the successful wet granulation of artesunate and mefloquine. A fractional factorial design identified the optimum factors and factor levels. The application of the granulation fluid (20% w/w) proved to be sufficient by a spraying method for both artesunate and mefloquine. A compatible acrylic polymer and coating agent for artesunate, Eudragit® L100 was employed to delay the release of approximately half of the artesunate dose from the double fixed-dose combination tablet until a pH of 6.8.
A compressible mixture was identified and formulated to contain 200 mg of artesunate and 415 mg of mefloquine per tablet. The physical properties of the tablets complied with BP standards.
An HPLC method from available literature was adapted and validated for analytical procedures. Dissolution studies according to a USP method were conducted to verify and quantify the release of the APIs in the double fixed-dose combination. The initial dissolution rate (DRi) of artesunate and mefloquine in the acidic dissolution medium was rapid as required. The enteric coated fraction of the artesunate exhibited no release in an acidic environment after 2 hours, but rapid release in a medium with a pH of 6.8. The structure of the granulated particles of mefloquine may have contributed to its first order release profile in the dissolution mediums. A linear correlation was present between the rate of mefloquine release and the percentage of mefloquine dissolved (R2 = 0.9484). Additionally, a linear relationship was found between the logarithm of the percentage mefloquine remaining against time (R2 = 0.9908). First order drug release is the dominant release profile found in the pharmaceutical industry today and is coherent with the kinetics of release obtained for mefloquine.
A concept pre-clinical phase, double fixed-dose combination solid oral dosage form for artesunate and mefloquine was developed. The double fixed-dose combination was designed in accordance with the WHO’s recommendation for an oral dosage regimen of artesunate and mefloquine for the treatment of uncomplicated falciparum malaria. The specifications of the double fixed-dose combination were developed in close accordance with the FDA’s quality by design concept and WHO recommendations. An HPLC analytical procedure was developed to verify the presence of artesunate and mefloquine. The dissolution profiles of artesunate and mefloquine were investigated during the dissolution studies. / PhD (Pharmaceutics), North-West University, Potchefstroom Campus, 2014
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Development and evaluation of a solid oral dosage form for an artesunate and mefloquine drug combination / Abel Hermanus van der WattVan der Watt, Abel Hermanus January 2014 (has links)
Malaria affects about forty percent of the world’s population. Annually more than 1.5 million fatalities due to malaria occur and parasite resistance to existing antimalarial drugs such as mefloquine has already reached disturbingly high levels in South-East Asia and on the African continent. Consequently, there is a dire need for new drugs or formulations in the prophylaxis and treatment of malaria. Artesunate, an artemisinin derivative, represents a new category of antimalarials that is effective against drug-resistant Plasmodium falciparum strains and is of significance in the current antimalarial campaign. As formulating an ACT double fixed-dose combination is technically difficult, it is essential that fixed-dose combinations are shown to have satisfactory ingredient compatibility, stability, and dissolution rates similar to the separate oral dosage forms.
Since the general deployment of a combination of artesunate and mefloquine in 1994, the cure rate increased again to almost 100% from 1998 onwards, and there has been a sustained decline in the incidence of Plasmodium falciparum malaria in the experimental studies (Nosten et al., 2000:297; WHO, 2010:17). However, the successful formulation of a solid oral dosage form and fixed dosage combination of artesunate and mefloquine remains both a market opportunity and a challenge.
Artesunate and mefloquine both exhibited poor flow properties. Furthermore, different elimination half-lives, treatment dosages as well as solubility properties of artesunate and mefloquine required different formulation approaches. To substantiate the FDA’s pharmaceutical quality by design concept, the double fixed-dose combination of artesunate and mefloquine required strict preliminary formulation considerations regarding compatibility between excipients and between the APIs. Materials and process methods were only considered if theoretically and experimentally proved safe. Infrared absorption spectroscopy (IR) and X-ray powder diffraction (XRPD) data proved compatibility between ingredients and stability during the complete manufacturing process by a peak by peak correlation. Scanning Electron Micrographs (SEM) provided explanations for the inferior flow properties exhibited by the investigated APIs. Particle size analysis and SEM micrographs confirmed that the larger, rounder and more consistently sized particles of the granulated APIs contributed to improved flow under the specified testing conditions.
A compressible mixture containing 615 mg of the APIs in accordance with the WHO recommendation of 25 mg/kg of mefloquine taken in two or three divided dosages, and 4 mg/kg/day for 3 days of artesunate for uncomplicated falciparum malaria was developed. Mini-tablets of artesunate and mefloquine were compressed separately and successfully with the required therapeutic dosages and complied with pharmacopoeial standards. Preformulation studies eventually led to a formula for a double fixed-dose combination and with the specific aim of delaying the release of artesunate due to its short half-life.
A factorial design revealed the predominant factors contributing to the successful wet granulation of artesunate and mefloquine. A fractional factorial design identified the optimum factors and factor levels. The application of the granulation fluid (20% w/w) proved to be sufficient by a spraying method for both artesunate and mefloquine. A compatible acrylic polymer and coating agent for artesunate, Eudragit® L100 was employed to delay the release of approximately half of the artesunate dose from the double fixed-dose combination tablet until a pH of 6.8.
A compressible mixture was identified and formulated to contain 200 mg of artesunate and 415 mg of mefloquine per tablet. The physical properties of the tablets complied with BP standards.
An HPLC method from available literature was adapted and validated for analytical procedures. Dissolution studies according to a USP method were conducted to verify and quantify the release of the APIs in the double fixed-dose combination. The initial dissolution rate (DRi) of artesunate and mefloquine in the acidic dissolution medium was rapid as required. The enteric coated fraction of the artesunate exhibited no release in an acidic environment after 2 hours, but rapid release in a medium with a pH of 6.8. The structure of the granulated particles of mefloquine may have contributed to its first order release profile in the dissolution mediums. A linear correlation was present between the rate of mefloquine release and the percentage of mefloquine dissolved (R2 = 0.9484). Additionally, a linear relationship was found between the logarithm of the percentage mefloquine remaining against time (R2 = 0.9908). First order drug release is the dominant release profile found in the pharmaceutical industry today and is coherent with the kinetics of release obtained for mefloquine.
A concept pre-clinical phase, double fixed-dose combination solid oral dosage form for artesunate and mefloquine was developed. The double fixed-dose combination was designed in accordance with the WHO’s recommendation for an oral dosage regimen of artesunate and mefloquine for the treatment of uncomplicated falciparum malaria. The specifications of the double fixed-dose combination were developed in close accordance with the FDA’s quality by design concept and WHO recommendations. An HPLC analytical procedure was developed to verify the presence of artesunate and mefloquine. The dissolution profiles of artesunate and mefloquine were investigated during the dissolution studies. / PhD (Pharmaceutics), North-West University, Potchefstroom Campus, 2014
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