Impact of active pharmaceutical ingredient variables and oleaginous base on the in vitro drug release from ophthalmic ointments: An investigation using dexamethasone as a model drug.

The present study systematically investigates the impact of active pharmaceutical ingredient (API) variables and oleaginous base characteristics on the in vitro release (IVR) performance of ophthalmic ointments, utilizing dexamethasone as a model drug. The interplay between selected attributes (i.e., particle size distribution, crystallinity, and polymorphic form for API, and rheological factors for compendial-grade white petrolatum) and IVR performance was investigated. APIs from different vendors exhibited variations in crystallinity and polymorphism. Ointments containing amorphous dexamethasone presented higher release amounts/rates compared to crystalline counterparts, emphasizing the role of physical state in release kinetics. Variations in particle size of this lipophilic API (5.4 - 21.2 µm) did not appear to impact IVR performance significantly. In contrast, white petrolatum's rheological attributes, which varied substantially within USP-grade petrolatum, were found to critically affect the drug release rate and extent of the ointment. The study's comprehensive analysis establishes a coherent connection between the quality attributes of both API and petrolatum and IVR, delineating their intricate interdependent effects on ophthalmic ointment performance. These findings provide reference to formulation design, quality control, and regulatory considerations within the pharmaceutical industry, fostering a robust foundational understanding of commonly overlooked quality attributes in ophthalmic ointments.

Impact of Apparatus and Adapter on In vitro Drug Release of Ophthalmic Semisolid Drug Products.

PURPOSE: In vitro release testing (IVRT) is a widely used tool for evaluating the quality and performance of drug products. However, standardized sample adaptors or drug release apparatus setups for IVRT studies are still lacking for ophthalmic ointments. The aim of this study was to provide a better understanding of the impact of apparatus and sample adaptor setups on IVRT of ophthalmic ointments. METHODS: Dexamethasone (DEX), a steroidal ingredient commonly used in ophthalmic drug products, was selected as a model drug. Ointments were prepared by mixing DEX in white petrolatum using a high shear mixer. A novel two-sided adapter was developed to increase the drug release surface area. DEX ointment was placed in one-sided or two-sided release adaptors coupled with 1.2 µm polyethersulfone membrane, and the drug release was studied in different USP apparatuses (I, II, and IV). RESULTS: The sample adaptor setups had a minimal impact on cumulative drug release amount per area or release rate while USP IV apparatus with agitated flow enhanced drug release rates. The USP apparatus I with a two-sided semisolid adapter, which uses membranes on both sides, showed dramatically higher cumulative drug release and discriminative release profiles when evaluating ophthalmic formulations. CONCLUSIONS: USP apparatuses and sample adaptors are critical considerations for IVRT. Two-sided semisolid adapter provides higher cumulative release, facilitating the discrimination between low drug content ophthalmic ointment formulations with good sensitivity and repeatability without affecting the drug release rate.

Topical pharmacokinetics of brinzolamide suspensions in rabbits and variability analysis for sample size and design considerations.

Identifying critical attributes for complex locally acting ophthalmic formulations and establishing in vitro-in vivo correlations can facilitate selection of appropriate thresholds for formulation changes that reflect lack of impact on in vivo performance. In this study the marketed antiglaucoma product Azopt® (1% brinzolamide suspension) and five other brinzolamide formulations varying in particle size distributions and apparent viscosities were topically administered in rabbits, and their ocular pharmacokinetics was determined in multiple ocular tissues. Statistical evaluation with ANOVA showed no significant differences between the formulations in the peak drug concentration (Cmax) in the aqueous humor and iris-ciliary body. As a post-hoc analysis, the within animal and total variability was determined for Cmax in the aqueous humor and iris-ciliary body. Based on the observed variability, we investigated the sample size needed for two types of study designs to observe statistically significant differences in Cmax. For the sample size calculations, assuming both 25% and 50% true differences in Cmax between two formulations, two study designs were compared: paired-eye dosing design (one formulation in one eye and another formulation in the other eye of the same animal at the same time) versus parallel-group design. The number of rabbits needed in the paired-eye dosing design are much lower than in the parallel-group design. For example, when the true difference in aqueous humor Cmax is 25%, nine rabbits are required in the paired-eye design versus seventy rabbits (35 per treatment) in the parallel-group design to observe a statistically significant difference with a power of 80%. Therefore, the proposed paired-eye dosing design is a viable option for the design of pharmacokinetic studies comparing ophthalmic products to determine the impact of formulation differences.

Stealth oxime ether lipid vesicles promote delivery of functional DsiRNA in human lung cancer A549 tumor bearing mouse xenografts.

We previously reported that hydroxylated oxime ether lipids (OELs) efficiently deliver functional Dicer substrate siRNAs (DsiRNAs) in cells. Here, we explored in vivo utility of these OELs, using OEL4 as a prototype and report that surface modification of the OEL4 formulations was essential for their in vivo applications. These surface-modified OEL4 formulations were developed by inclusion of various PEGylated lipids. The vesicle stability and gene knock-down were dependent on the PEG chain length. OEL4 containing DSPE-PEG350 and DSPE-PEG1000 (surprisingly not DSPE2000) promoted gene silencing in cells. In vivo studies demonstrated that OEL4 vesicles formulated using 3 mol% DSPE-PEG350 accumulate in human lung cancer (A549-luc2) xenografts in mice and exhibit a significant increase in tumor to liver ratios. These vesicles also showed a statistically significant reduction of luciferase signal in tumors compared to untreated mice. Taken together, the scalable OEL4:DSPE-PEG350 formulation serves as a novel candidate for delivery of RNAi therapeutics.

Impact of formulation on the quality and stability of freeze-dried nanoparticles.

Freeze-drying is an effective approach to improve the long-term stability of nanomedicines. Lyoprotectants are generally considered as requisite excipients to ensure that the quality of nanoparticles is maintained throughout the freeze-drying process. However, depending on the type of nanoparticles, the needs for lyoprotectants or the challenges they face during freeze-drying may be different. In this study, we compared and identified the impact of freeze-drying on key characteristics of three types of nanoparticles: solid lipid nanoparticles (SLNs), polymeric nanoparticles (PNs), and liposomes. Sucrose, trehalose, and mannitol were added to nanoparticle suspensions before freeze-drying. The same conservative freeze-drying conditions with controlled ice nucleation at -8 °C were employed for all formulations. The collapse temperatures of nanoparticle formulations were found to be the same as those of the lyoprotectant added, except PN formulation. Likely the poly(vinyl alcohol) (PVA) in the formulation induced a higher collapse temperature and retardation of drying of PNs. Freeze-drying of both SLNs and liposomes without lyoprotectants increased particle size and polydispersity, which was resolved by adding amorphous disaccharides. Regardless of the addition of lyoprotectants, freeze-drying did not alter the size of PNs possibly due to the protection from PVA. However, lyoprotectants were still necessary to shorten the reconstitution time and reduce the residual moisture. In conclusion, different types of nanoparticles face distinct challenges for freeze-drying, and lyoprotectants differentially affect various stability and quality attributes of freeze-dried nanoparticles.

Stabilization and X-ray Attenuation of PEGylated Cholesterol/Polycaprolactone-Based Perfluorooctyl Bromide Nanocapsules for CT Imaging.

Contrast-enhanced X-ray computed tomography plays an important role in cancer imaging and disease progression monitoring. Imaging using radiopaque nanoparticle platforms can provide insights on the likelihood of nanoparticle accumulation and can enable image-guided therapies. Perfluorooctyl bromide (PFOB)-loaded nanocapsules designed for this purpose were stabilized using an in-house synthesized PEGylated polycaprolactone-based copolymer (PEG-b-PCL(Ch)) and compared with commercial polycaprolactone employing a Quality-by-Design approach. PFOB is a dense liquid, weakly polarizable, and immiscible in organic and aqueous solvents; thus, carefully designed formulations for optimal colloidal stabilization to overcome settling-associated instability are required. PFOB-loaded nanocapsules exhibited high PFOB loading due to the intrinsic properties of PEG-b-PCL(Ch). Settling and caking are major sources of instability for PFOB formulations. However, the PEG-b-PCL(Ch) copolymer conferred the nanocapsules enough steric impediment and polymer shell elasticity to settle without significant caking, increasing the overall colloidal stability of the formulation. Furthermore, a clear relationship between nanocapsule physical properties and X-ray attenuation was established. Nanocapsules were able to enhance the X-ray contrast in vitro as a function of PFOB loading. This nanocapsule-based platform is promising for future translational studies and image-guided tumor therapy due to its enhanced contrastability and optimal colloidal stability.

Applications of Nanoparticle-Antibody Conjugates in Immunoassays and Tumor Imaging.

Modern diagnostic technologies rely on both in vitro and in vivo modalities to provide a complete understanding of the clinical state of a patient. Nanoparticle-antibody conjugates have emerged as promising systems to confer increased sensitivity and accuracy for in vitro diagnostics (e.g., immunoassays). Meanwhile, in vivo applications have benefited from the targeting ability of nanoparticle-antibody conjugates, as well as payload flexibility and tailored biodistribution. This review provides an encompassing overview of nanoparticle-antibody conjugates, from chemistry to applications in medical immunoassays and tumor imaging, highlighting the underlying principles and unique features of relevant preclinical applications employing commonly used imaging modalities (e.g., optical/photoacoustics, positron-emission tomography, magnetic resonance imaging, X-ray computed tomography).

The role of sodium alginate on the supersaturation state of the poorly soluble drug chlorthalidone.

Solid dispersions (SDs) of chlorthalidone (CTD) are promising systems to enhance drug dissolution rate, generate and maintain drug supersaturation levels in gastrointestinal fluids. In this work, SDs of CTD were prepared by spray drying using sodium alginate (SA) as carrier. Six formulations were prepared, varying the drug loading and composition, through the combination of SA with surfactants (sodium lauryl sulfate (SLS) or polyvinyl caprolactam-polyvinyl acetate-polyethylene glycol graft copolymer (SOL)). In all SDs, except when SA was used alone at low drug loading, CTD was in the amorphous form. At sink conditions, all SDs showed a faster dissolution rate than the crystalline drug. At non-sink conditions, the SDs prepared with SA and SLS at low drug loading exhibited the best performance to maintain supersaturating drug levels. All SDs, except those prepared with SA alone or SA-SLS at high drug loading, presented no drug recrystallization after 34 months of storage.

Evaluation of dermal tissue regeneration using resveratrol loaded fibrous matrix in a preclinical mouse model of full-thickness ischemic wound.

The complete loss of dermal tissue due to ischemia is a serious challenge facing clinicians. Frequently, the failure of wound healing is due to ischemic conditions prevailing at the site of damaged tissue. Restoration of lost vasculature at the ischemic site can be achieved by supplementing proangiogenic stimuli through an engineered scaffold mimicking dermal extracellular matrix. Towards this objective, we have developed an electrospun scaffold loaded with the pro-angiogenic molecule resveratrol. The physical and chemical changes in the polymeric scaffold before and after loading of resveratrol were characterized using field emission scanning electron microscopy (FE-SEM), Fourier-transform infrared spectroscopy (FT-IR), differential scanning calorimetry (DSC), thermogravimetric analysis (TGA), coherence scanning interferometry (CSI) and X-ray diffraction (XRD). A sustained release of resveratrol from the scaffold was elucidated by UV-spectrophotometer analysis. The enhancement in cell-matrix interaction was studied using human umbilical vein endothelial cells (HUVECs) seeded on the scaffolds. The biocompatibility analysis of resveratrol loaded scaffolds was evaluated through a subcutaneous implantation study in mice. The therapeutic potential of resveratrol loaded scaffolds to accelerate tissue repair was analyzed in a full-thickness ischemic wound model in mice. Wound closure and H&E staining analysis showed rapid closure of ischemic wound area and re-epithelialization in resveratrol loaded scaffold treated groups compared to collagen and negative control groups. The immunostaining analysis further revealed the activation of thioredoxin-1 (Trx-1), heme oxygenase-1 (HO-1) mediated vascular endothelial growth factor (VEGF) signaling in resveratrol loaded scaffold treated group. The expression of Bcl-2 in healing wound edges post-treatment with resveratrol loaded scaffold confirmed the anti-apoptotic effect mediated by resveratrol. From this study, we explored a synergistic effect mediated by resveratrol and fibrous scaffolds to aid the ischemic wound healing process through effective vascularization.

Preparation, characterization and application of a protein hydrogel with rapid self-healing and unique autofluoresent multi-functionalities.

A smart hydrogel with dual self-healing and autofluoresent functionalities is presented. The protein hydrogel is fabricated by denaturing bovine serum albumin in a basic environment. Upon gelation, autofluorescence is induced and the protein hydrogel can be excited by a wide range of spectrum, ranging from 320 to 520 nm. It was also found that the as-prepared autofluorescent protein hydrogel possessed rapid and repetitive self-healing capability. Without any external stimulus, more than 90% recovery of the mechanical strength can be obtained within 10 min after destruction. Moreover, the as-prepared hydrogel exhibits excellent biocompatibility and cell attachment property after its pH adjustment to neutral pH, while both autofluorescence and self-healing properties were still retained. This study suggests a promising means to prepare multi-functional protein hydrogel with dual physicochemical functionalities, which holds great potential in biomedical related applications. © 2018 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 107A: 81-91, 2019.

Liquisolid systems: Understanding the impact of drug state (solution or dispersion), nonvolatile solvent and coating material on simvastatin apparent aqueous solubility and flowability.

The drug in a solid dosage form must undergo dissolution before it is available for absorption from the gastrointestinal tract. Liquisolid system (LS) is a technology used for increasing aqueous solubility of the drugs, which has an important role in the dissolution and absorption phenomena. However, many factors can influence the performance and success of LS. Therefore this study aimed to evaluate through a factorial design, the factors such as drug state (solution or dispersion), nonvolatile solvent and coating material that influence the increase simvastatin (BSC II drug) apparent aqueous solubility and LS flow properties. Through numerical optimization the best formulation was selected to develop a liquisolid compact (LC) and it was evaluated by dissolution tests over commercial tablets using two dissolution media. Analyzing the data, the type of nonvolatile solvent and the state of the drug (solution or dispersion) were the factors with the greatest effects on the apparent aqueous solubility response (p < 0.0001 for both). Regarding the responses that evaluated the flow properties, the type of coating material and the type of nonvolatile solvent were the factors that influenced the Carr index (p < 0.0006, p < 0.0023, respectively) and Hausner ratio (p < 0.0006, p < 0.0014, respectively), where formulations containing Kollidon® CL were more efficient than Aerosil® (which is the most commonly used coating material for LS manufacture). These results enabled us to identify which factors were most influential and to move towards the use of new excipients in the case of Kollidon® CL. In addition, allowed a wider evaluation and understanding of LS, which is considered an important technological alternative for the increase of drug solubility.

Green clay and aloe vera peel-off facial masks: response surface methodology applied to the formulation design.

This article describes the optimization of a peel-off facial mask formulation. An investigation was carried out on the parameters of the formulation that most affect the desirable characteristics of peel-off facial masks. Cereal alcohol had a significant effect on the drying time at concentrations of 1-12% (w/w). The applicability of the evaluated formulations was influenced by both carbomer (0-2.4%; w/w) and polyvinyl alcohol (PVA; 2.5-17.5%; w/w) content due to their ability to alter the formulation viscosity. Inverse concentrations of carbomer and PVA led to formulations with optimum viscosity for facial application. Film-forming performance was influenced only by the PVA concentration, achieving maximum levels at concentrations of around 11% (w/w). The optimized formulation, determined mathematically, contained 13% (w/w) PVA and 10% (w/w) cereal alcohol with no addition of carbomer. This formulation provided high levels of applicability and film-forming performance, the lowest drying time possible and excellent homogeneity of the green clay particles and aloe vera before and after drying. The preliminary stability study indicated that the optimized formulation is stable under normal storage conditions. The microbiological stability evaluation indicated that the preservative was efficient in terms of avoiding microbial growth. RSM was shown to be a useful statistical tool for the determination of the behavior of different compounds and their concentrations for the responses studied, allowing the investigation of the optimum conditions for the production of green clay and aloe vera peel-off facial masks.