Mucoadhesive delivery systems have attracted remarkable interest recently, especially for their potential to prolong dosage form resident times at sites of application such as the vagina or nasal ...cavity, thereby improving convenience and compliance as a result of less frequent dosage. Mucoadhesive capabilities need to be routinely quantified during the development of these systems. This is however logistically challenging due to difficulties in obtaining and preparing viable mucosa tissues for experiments. Utilizing artificial membranes as a suitable alternative for quicker and easier analyses of mucoadhesion of these systems is currently being explored. In this study, the mucoadhesive interactions between progesterone-loaded fibers (with varying carboxymethyl cellulose (CMC) content) and either artificial (cellulose acetate) or mucosa membranes are investigated by texture analysis and results across models are compared. Mucoadhesion to artificial membrane was about 10 times that of mucosa, though statistically significant ( p = 0.027) association between the 2 data sets was observed. Furthermore, a hypothesis relating fiber-mucosa interfacial roughness (and unfilled void spaces on mucosa) to mucoadhesion, deduced from some classical mucoadhesion theories, was tested to determine its validity. Points of interaction between the fiber and mucosa membrane were examined using atomic force microscopy (AFM) to determine the depths of interpenetration and unfilled voids/roughness, features crucial to mucoadhesion according to the diffusion and mechanical theories of mucoadhesion. A Kendall's tau and Goodman-Kruskal's gamma tests established a monotonic relationship between detaching forces and roughness, significant with p-values of 0.014 and 0.027, respectively. A similar relationship between CMC concentration and interfacial roughness was also confirmed. We conclude that AFM analysis of surface geometry following mucoadhesion can be explored for quantifying mucoadhesion as data from interfacial images correlates significantly with corresponding detaching forces, a well-established function of mucoadhesion.
Solid dispersions in water-soluble carriers have attracted considerable interest as a means of improving the dissolution rate, and hence possibly bioavailability, of a range of hydrophobic drugs. ...However, despite the publication of numerous original papers and reviews on the subject, the mechanisms underpinning the observed improvements in dissolution rate are not yet understood. In this review the current consensus with regard to the solid-state structure and dissolution properties of solid dispersions is critically assessed. In particular the theories of carrier- and drug-controlled dissolution are highlighted. A model is proposed whereby the release behaviour from the dispersions may be understood in terms of the dissolution or otherwise of the drug into the concentrated aqueous polymer layer adjacent to the solid surface, including a derivation of an expression to describe the release of intact particles from the dispersions. The implications of a deeper understanding of the dissolution mechanisms are discussed, with particular emphasis on optimising the choice of carrier and manufacturing method and the prediction of stability problems.
A one-pot single-step novel process has been developed to form microbubbles up to 250 μm in diameter using a pressurized rotating device. The microbubble diameter is shown to be a function of ...rotational speed and working pressure of the processing system, and a modified Rayleigh–Plesset equation has been derived to explain the bubble-forming mechanism. A parametric plot is constructed to identify a rotating speed and working pressure regime, which allows for continuous bubbling. Bare protein (lysozyme) microbubbles generated in this way exhibit a morphological change, resulting in microcapsules over a period of time. Microbubbles prepared with gold nanoparticles at the bubble surface showed greater stability over a time period and retained the same morphology. The functionalization of microbubbles with gold nanoparticles also rendered optical tunability and has promising applications in imaging, biosensing, and diagnostics.
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Microneedles (MN) have emerged as an innovative technology for drug delivery, offering a minimally invasive approach to administer therapeutic agents. Recent applications have ...included ocular drug delivery, requiring the manufacture of sub-millimeter needle arrays in a reproducible and reliable manner. The development of 3D printing technologies has facilitated the fabrication of MN via mold production, although there is a paucity of information available regarding how the printing parameters may influence crucial issues such as sharpness and penetration efficacy. In this study, we have developed and optimized a 3D-printed MN micro-mold using stereolithography (SLA) 3D printing to prepare a dissolving ocular MN patch. The effects of a range of parameters including aspect ratio, layer thickness, length, mold shape and printing orientation have been examined with regard to both architecture and printing accuracy of the MN micro-mold, while the effects of printing angle on needle fidelity was also examined for a range of basic shapes (conical, pyramidal and triangular pyramidal). Mechanical strength and in vitro penetration of the polymeric (PVP/PVA) MN patch produced from reverse molds fabricated using MN with a range of shapes and height, and aspect ratios were assessed, followed by ex vivo studies of penetration into excised scleral and corneal tissues. The optimization process identified the parameters required to produce MN with the sharpest tips and highest dimensional fidelity, while the ex vivo studies indicated that these optimized systems would penetrate the ocular tissue with minimal applied pressure, thereby allowing ease of patient self-administration.
Electrospinning is increasingly becoming a viable means of producing drug delivery vehicles for oral delivery, particularly as issues of manufacturing scalability are being addressed. In this study, ...electrospinning is explored as a taste-masking manufacturing technology for bitter drugs. The taste-masking polymer Eudragit E PO (E-EPO) was electrospun, guided by a quality by design approach. Using a design of experiment, factors influencing the production of smooth fibers were investigated. Polymer concentration, solvent composition, applied voltage, flow rate, and gap distance were the parameters examined. Of these, polymer concentration was shown to be the only statistically significant factor within the ranges studied ( p-value = 0.0042). As the concentration increased, smoother fibers were formed, coupled with an increase in fiber diameter. E-EPO (35% w/v) was identified as the optimum concentration for smooth fiber production. The optimized processing conditions identified were a gap distance of 175 mm, an applied voltage of between 15 and 20 kV, and a flow rate of 1 mL/h. Using this knowledge, the production optimization of electrospun E-EPO with chlorpheniramine maleate (CPM), a bitter antihistamine drug, was explored. The addition of CPM in drug loads of 1:6 up to 1:10 CPM/E-EPO yielded smooth fibers that were electrospun under conditions similar to placebo fibers. Solid-state characterization showed CPM to be molecularly dispersed in E-EPO. An electronic tasting system, or E-tongue, indicated good taste-masking performance as compared to the equivalent physical mixtures. This study therefore describes a means of producing, optimizing, and assessing the performance of electrospun taste-masked fibers as a novel approach to the formulation of CPM and potentially other bitter drug substances.
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Corneal abrasion is a scratch wound on the surface of the anterior segment of the eye, which can predispose a patient to corneal infection and scarring, particularly if the cut ...penetrates to the deep corneal layers. Here we investigate a novel approach to co-administer an anti-scarring agent and an antibiotic, both being incorporated into one dosage form so as to accelerate wound closure and to treat any associated infection. More specifically, we have used electrospun fibers as a means of incorporating the two drugs into distinct compartments via coaxial electrospinning. Samples were characterised using a range of imaging, spectroscopic and thermal methods, while an HPLC assay has been developed to allow measurement of the concentration of both drug components in both the initial fibers and on release. Fibers loaded with pirfenidone in the hydrophobic polymer, PLGA, as the outer layer and moxifloxacin in the hydrophilic polymer PVP as the inner layer were successfully prepared, with smooth and non-porous surfaces and a mean diameter of circa 630 nm. TEM image demonstrated clear distinctive layers (a core and a shell), suggesting the successful preparation of the drug-loaded coaxial fibers, supported by HPLC entrapment studies, while fluorescence microscopy confirmed the presence of the moxifloxacin within the fibers. The fibers were capable of extending the release of both drugs, hence raising the possibility of a single daily dose of the drug-loaded coaxial fibers for the treatment of corneal abrasion.
Adeno-associated viral vectors (AAVs) have proved a mainstay in gene therapy, owing to their remarkable transduction efficiency and safety profile. Their production, however, remains challenging in ...terms of yield, the cost-effectiveness of manufacturing procedures and large-scale production. In this work, we present nanogels produced by microfluidics as a novel alternative to standard transfection reagents such as polyethylenimine-MAX (PEI-MAX) for the production of AAV vectors with comparable yields. Nanogels were formed at pDNA weight ratios of 1 : 1 : 2 and 1 : 1 : 3, of pAAV
-plasmid, pDG9 capsid
-plasmid and pHGTI helper plasmid respectively, where vector yields at a small scale showed no significant difference to those of PEI-MAX. Weight ratios of 1 : 1 : 2 showed overall higher titers than 1 : 1 : 3, where nanogels with nitrogen/phosphate ratios of 5 and 10 produced yields of ≈8.8 × 10
vg mL
and ≈8.1 × 10
vg mL
respectively compared to ≈1.1 × 10
vg mL
for PEI-MAX. In larger scale production, optimised nanogels produced AAV at a titer of ≈7.4 × 10
vg mL
, showing no statistical difference from that of PEI-MAX at ≈1.2 × 10
vg mL
, indicating that equivalent titers can be achieved with easy-to-implement microfluidic technology at comparably lower costs than traditional reagents.
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This study describes the preparation of free films of zein with and without acetylated high amylose maize starch (HAS) and their corresponding coated tablets as a novel approach to ...colonic drug delivery. We hypothesise that the embedding of a digestible starch component within the inert zein would allow the film to remain intact until the large intestine is reached. Free films of zein alone and starch/zein were prepared and characterized. SEM and AFM images of film surface showed that films were morphologically inhomogeneous, particularly at lower HAS/Zein ratios; however, nanothermal analysis data suggested that these differences in appearance within the same film are not compositional differences. Moreover, FT-IR could detect no molecular interaction between the two polymers. Paracetamol tablets were coated with HAS/Zein aqueous based coatings of different compositions to a TWG of 20%. Drug release from zein alone and 1:5 HAS/Zein coated tablets under upper gastrointestinal conditions (pH 1.2, pH 6.8 with pepsin and pancreatin included) was very similar (for example approximately 12% and 14% of the drug was released, respectively, after 6 h in a sequential in vitro test), suggesting that release in this region is limited and is not influenced by the presence of HAS in the ratio to zein under study. Studies using an in vitro colon model showed that under simulated colonic conditions, the drug release was significantly (p < 0.05) more rapid from 1:5 HAS/Zein, compared to the zein alone coating formulation. These data therefore support the potential use of zein-starch mixed films for colonic targeting purposes.
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•Gyration under pressure was used to spin PET nanofibres.•Teas graph was mapped to identify the solubility–spinnability region.•Scaling law was found for relationship between polymer ...concentration and viscosity.•Structural evolution in PET nanofibres is explained.•Mathematical model has been developed to predict fibre diameter.
The selection of a solvent or a solvent system is a fundamental and a crucial step in spinning fibres using a selected process. Solvent selection determines the critical minimum polymer concentration and the critical minimum chain entanglement which allows the spinning of nanofibres rather than other hybrid morphologies such as beaded structures. Pressurised gyration, which simultaneously combines the use of gas pressure and rotation, is used as the processing and forming route for spinning fibres in this work. This study investigates 23 different solvents and solvent systems spread on a wide area of a Teas graph and able to dissolve the functional polymer polyethylene (terephthalate) (PET) and spin products by the application of pressurised gyration. The results are mapped on a Teas graph to identify the solubility–spinnability region. Based on this solubility–spinnability region, various solvents and binary solvent systems that allow the making of PET fibres are suggested. Scaling laws for the relationship between polymer concentration and specific viscosity are identified. The structural evolution in the fibres prepared is elucidated. For the first time, a mathematical model to scale fibre diameter with respect to flow properties and processing parameters encountered in pressurised gyration has been successfully developed.
Microneedles (MNs) have attracted considerable interest as a means of ocular drug delivery, a challenging delivery route due to the limitations imposed by the various biological barriers associated ...with this organ. In this study, a novel ocular drug delivery system was developed by formulating a dissolvable MN array containing dexamethasone-loaded PLGA microparticles for scleral drug deposition. The microparticles serve as a drug reservoir for controlled transscleral delivery. The MNs displayed sufficient mechanical strength to penetrate the porcine sclera. Dexamethasone (Dex) scleral permeation was significantly higher than in topically instilled dosage forms. The MN system was able to distribute the drug through the ocular globe, with 19.2% of the administered Dex detected in the vitreous humour. Additionally, images of the sectioned sclera confirmed the diffusion of fluorescent-labelled microparticles within the scleral matrix. The system therefore represents a potential approach for minimally invasive Dex delivery to the posterior of the eye, which lends itself to self-administration and hence high patient convenience.