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Prediction of interacting motifs within the protein subunits of Picornavirus capsids
- Authors: Ross, Caroline Jane
- Date: 2015
- Subjects: Picornaviruses , Antiviral agents , Poliovirus , Coxsackieviruses , Hepatitis A virus , Foot-and-mouth disease virus , Viral proteins
- Language: English
- Type: Thesis , Masters , MSc
- Identifier: vital:4151 , http://hdl.handle.net/10962/d1017912
- Description: The Picornaviridae family contains a number of pathogens which are economically important including Poliovirus, Coxsakievirus, Hepatitis A Virus, and Foot-and-Mouth-Disease-Virus. Recently the emergence of novel picornaviruses associated with gastrointestinal, neurological and respiratory diseases in humans has been reported. Although effective vaccines for viruses such as FMDV, PV and HAV have been developed there are currently no antivirals available for the treatment of picornavirus infections. Picornaviruses proteins are classified as: the structural proteins VP1, VP2, VP3 and VP4 which form the subunits of the viral capsid and the replication proteins which function as proteases, RNA-polymerases, primers and membrane binding proteins. Although the host specificity and viral pathogenicity varies across members of the family, the icosahedral capsid is highly conserved. The capsid consists of 60 protomers, each containing a single copy of VP1, VP2 and VP3. A fourth capsid protein, VP4, resides on the internal side of the capsid. Capsid assembly is integral to life-cycle of picornaviruses; however the process is complex and not fully-understood. The overall aim of the study was to broaden the understanding of the evolution and function of the structural proteins across the Picornaviridae family. Firstly a comprehensive analysis of the phylogenetic relationships amongst the individual structural proteins was performed. The functions of the structural proteins were further investigated by an exhaustive motif analysis. A subsequent structural analysis of highly conserved motifs was performed with respect to representative enteroviruses, Foot-and-Mouth-Disease-Virus and Theiler’s Virus. This was supplemented by the in silico prediction of interacting residues within the crystal structures of these protomers. Findings in this study suggest that the capsid proteins may be evolving independently from the replication proteins through possible inter-typic recombination of functional protein regions. Moreover the study predicts that protomer assembly may be facilitated through a network of multiple subunit-subunit interactions. Multiple conserved motifs and principle residues predicted to facilitate capsid subunit-subunit interactions were identified. It was also concluded that motif conservation may support the theory of inter-typic recombination between closely related virus sub-types. As capsid assembly is critical to the viral life-cycle, the principle interacting motifs may serve as novel drug targets for the antiviral treatment of picornavirus infections. Thus the findings in the study may be fundamental to the development of treatments which are more economically feasible or clinically effective than current vaccinations.
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Development, assessment and optimisation of oral famciclovir formulations for paediatric use
- Authors: Magnus, Laura
- Date: 2012
- Subjects: Drugs -- Dosage forms , Drugs -- Analysis , Capsules (Pharmacy) , Antiviral agents , Pediatrics
- Language: English
- Type: Thesis , Masters , MSc
- Identifier: vital:3870 , http://hdl.handle.net/10962/d1018244
- Description: Many Active Pharmaceutical Ingredients (API) such as the antiviral agent famciclovir (FCV) are required for paediatric treatment but are not commercially available in age-appropriate dosage forms. It is common practice to prepare oral liquid dosage forms using commercially available tablets, capsules or powdered API and then dispersing or dissolving the crushed and/or powdered materials in a vehicle that the patient can swallow. Vehicles that are commonly used for this purpose include methylcellulose, syrup or combinations of these carriers where possible or commercially available suspending agents such as Ora-Sweet®, if available, can be used. However, several critical factors are overlooked when manufacturing extemporaneous formulations including, but not limited to, physical and chemical properties of the API, excipients, compatibility, stability and bioavailability issues. A stability-indicating High Performance Liquid Chromatography (HPLC) method for the analysis of FCV was developed and validated according to the International Conference on Harmonization (ICH) guidelines. The method is sensitive, selective, precise, accurate and linear over the concentration range 2-120 μg/ml. The stability of 25 mg/ml FCV formulations was assessed in vehicles manufactured from syrup simplex, hydroxypropyl methylcellulose (HPMC), Ora-Sweet® and an aqueous buffer (pH 6) following storage at 25 °C/60% RH and 40 °C/75% RH over six (6) to eight (8) weeks. The shelf life of the products was calculated as the longest period of storage for approximately 90% of the added FCV to be recovered. Formulations were manufactured using syrup simplex or HPMC with methylparaben and propylparaben individually or in combination and with sodium metabisulphite, ascorbic acid or citric acid as antioxidants. The resultant products were subject to quality control analysis for API content, viscosity, pH and appearance and the resultant data were subject to statistical analysis. The degradation rates were calculated for each product and a degradation profile plotted. The degradation rates of FCV in extemporaneous formulations were compared to those of FCV manufactured using a commercially available suspending agent and a buffered vehicle. FCV undergoes major degradation in the presence of sucrose, as observed for formulations in which the vehicle was syrup and Ora-Sweet®. FCV was found to be most stable when dissolved/dispersed in an HPMC vehicle incorporating sodium metabisulphite and a combination of parabens. The formulation that exhibited the maximum stability was manufactured using an aqueous solution buffered to pH 6. Due to the enhanced stability of FCV when added to a buffered vehicle a formulation in which an HPMC vehicle buffered to pH 6 with sodium metabisulphite, methylparaben and propylparaben was selected for optimisation using a Central Composite Design approach (CCD). In this way it was possible to establish a relationship between input variables such as pH, % w/v HPMC, % w/v antioxidant and % w/v preservative and the responses selected for monitoring by means of response surface modelling. A quadratic model was found to be the most appropriate to describe the relationship between input and output variables. Thirty batches of product were randomly manufactured according to the CCD and analysed to establish the stability in respect of viscosity, pH and the amount of FCV remaining following storage and the data were fitted to models using Design-Expert® software. A correlation between input variables and the responses was best described by a quadratic polynomial model. Analysis of Variance indicated that the response surface models were significant (P-value < 0.0001). The pH to which a FCV formulation was buffered was the most significant factor to effect the % drug content and the ultimate pH of the formulation, while the % w/v HPMC had the most significant effect on the viscosity of the product. The optimum composition for the manufacture of an oral liquid FCV formulation was predicted using the optimisation function of the Design-Expert® software. A low % error of prediction was established, indicating that the model is robust and that RSM is an appropriate formulation optimisation tool as it has a high prognostic ability. A liquid FCV formulation was developed, optimised and found to be suitable for its intended purpose. However further optimisation is required in respect of colourants, sweeteners and/or flavourants. The approach followed is useful in ensuring the development of quality products and can be applied in future.
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