Advancements in Ocular Therapy: A Review of Emerging Drug Delivery Approaches and Pharmaceutical Technologies.

Eye disorders affect a substantial portion of the global population, yet the availability of efficacious ophthalmic drug products remains limited. This can be partly ascribed to a number of factors: (1) inadequate understanding of physiological barriers, treatment strategies, drug and polymer properties, and delivery systems; (2) challenges in effectively delivering drugs to the anterior and posterior segments of the eye due to anatomical and physiological constraints; and (3) manufacturing and regulatory hurdles in ocular drug product development. The present review discusses innovative ocular delivery and treatments, encompassing implants, liposomes, nanoparticles, nanomicelles, microparticles, iontophoresis, in situ gels, contact lenses, microneedles, hydrogels, bispecific antibodies, and gene delivery strategies.

Novel dissolution methods for drug release testing of Long-Acting injectables.

Long-acting parenteral drug products are a popular choice for therapeutic areas requiring long term treatment. These products range from dispersed systems such as drug suspensions and polymeric microspheres to in situ forming polymeric implants. The lack of reliable drug release testing methods for these drug products not only impedes the development of new drug products but also affects generic drug development.

Impact of manufacturing variables on product performance of contraceptive levonorgestrel intrauterine systems.

The development of Levonorgestrel Intrauterine Systems (LNG-IUSs) stands as a formidable challenge due to their intricate design and reliance on specialized manufacturing methods. Pharmaceutical manufacturers face a labyrinth of process variables that demand precise identification and comprehension to establish a robust product design to ensure consistent performance. The current manuscript navigates through this complexity, describing a small-scale processing method for LNG-IUSs via addition and condensation curing processes, as well as investigating the influence of key manufacturing variables on LNG-IUS product performance.

Development of Mechanistic In Vitro-In Vivo Extrapolation to Support Bioequivalence Assessment of Long-Acting Injectables.

Long-acting injectable (LAI) formulations provide sustained drug release over an extended period ranging from weeks to several months to improve efficacy, safety, and compliance. Nevertheless, many challenges arise in the development and regulatory assessment of LAI drug products due to a limited understanding of the tissue response to injected particles (e.g.

Tailoring drug release from long-acting contraceptive levonorgestrel intrauterine systems.

The wide array of polydimethylsiloxane (PDMS) variants available on the market, coupled with the intricate combination of additives in silicone polymers, and the incomplete understanding of drug release behavior make formulation development of levonorgestrel intrauterine systems (LNG-IUSs) formidable. Accordingly, the objectives of this work were to investigate the impact of excipients on formulation attributes and in vitro performance of LNG-IUSs, elucidate drug release mechanisms, and thereby improve product understanding. LNG-IUSs with a wide range of additives and fillers were prepared, and in vitro drug release testing was conducted for up to 12 months.

Hyper-spectra imaging analysis of PLGA microspheres via machine learning enhanced Raman spectroscopy.

Long-acting injectables (LAI) offer a cost-effective and patient-centric approach by reducing pill burden and improving compliance, leading to better treatment outcomes. Among various types of long-acting injectables, poly (lactic-co-glycolic acid) (PLGA) microspheres have been extensively investigated and reported in the literature. However, microsphere formulation development is still challenging due to the complexity of PLGA polymer, formulation screening, and processing, as well as time-consuming and cumbersome physicochemical characterization.

In situ forming risperidone implants: Effect of PLGA attributes on product performance.

Despite the unique advantages of injectable, long-acting in situ forming implant formulations based on poly(lactide-co-glycolide) (PLGA) and N-Methyl-2-Pyrrolidone (NMP), only six products are commercially available. A better understanding of PLGA will aid in the development of more in situ forming implant innovator and generic products. This article investigates the impact of slight changes in PLGA attributes, i.

In vivo characterization of Perseris and compositionally equivalent formulations.

Perseris is asubcutaneous extended-release risperidone in situ forming implant (suspension) indicated for the treatment of adult schizophrenia. Owing to the release rate controlling polymer poly(lactide-co-glycolide) (PLGA), one injection of Perseris can deliver risperidone for one month, which significantly reduces the administration frequency and improves patient compliance. The PLGA and drug used in Perseris was previously identified through reverse engineering and two compositionally equivalent formulations (F-1 and F-2) showing similar in vitro drug release were developed.

Investigating structural attributes of drug encapsulated microspheres with quantitative X-ray imaging.

The intra-sphere and inter-sphere structural attributes of controlled release microsphere drug products can greatly impact their release profile and clinical performance. In developing a robust and efficient method to characterize the structure of microsphere drug products, this paper proposes X-ray microscopy (XRM) combined with artificial intelligence (AI)-based image analytics. Eight minocycline loaded poly(lactic-co-glycolic acid) (PLGA) microsphere batches were produced with controlled variations in manufacturing parameters, leading to differences in their underlying microstructures and their final release performances.

Long-acting PLGA microspheres: Advances in excipient and product analysis toward improved product understanding.

Poly(lactic-co-glycolic acid) (PLGA) microspheres are a sustained-release drug delivery system with several successful commercial products used for the treatment of a variety of diseases. By utilizing PLGA polymers with different compositions, therapeutic agents can be released over durations varying from several weeks to several months. However, precise quality control of PLGA polymers and a fundamental understanding of all the factors associated with the performance of PLGA microsphere formulations remains challenging.

Long-Acting Injectable Aqueous Suspensions-Summary From an AAPS Workshop.

Through many years of clinical application of long-acting injectables, there is clear proof that this type of formulation does not just provide the patient with convenience, but more importantly a more effective treatment of the medication provided. The formulation approach therefore contains huge untapped potential to improve the quality of life of many patients with a variety of different diseases. This review provides a summary of some of the central talks provided at the workshop with focus on aqueous suspensions and their use as a long-acting injectable.

Reverse engineering of Perseris and development of compositionally equivalent formulations.

Six injectable, long-acting in situ forming implant drug products based on poly(lactide-co-glycolide) (PLGA) and N-Methyl-2-Pyrrolidone (NMP) are available on the market. However, generic products, which would likely be more affordable for patients, are not yet available. This is partially due to the unique complexity of these formulations as well as the inherent heterogeneity of PLGA and the challenges in the manufacture and characterization of this polymer.

Development of in vitro-in vivo correlations for long-acting injectable suspensions.

Long-acting injectable (LAI) aqueous suspensions achieve extended drug release over a duration of weeks to months via slow dissolution of drug crystals with low solubility. There have been around ten LAI aqueous suspensions approved by the FDA to date and there are no generic equivalents for most of them. This may be largely due to the complex formulation development as well as the challenges in establishment of in vitro-in vivo correlation (IVIVC) for these products.

Impact of drug loading on release from levonorgestrel intrauterine systems.

Levonorgestrel intrauterine systems (LNG-IUSs) are polydimethylsiloxane (PDMS) based non-biodegradable complex drug-device combination products providing efficacy for up to several years based on the strength. A large amount of LNG (e.g.

Long-acting intrauterine systems: Recent advances, current challenges, and future opportunities.

Levonorgestrel intrauterine systems (LNG-IUSs) are complex drug-device combination products designed to release a hormonal contraceptive drug for up to 7 years. These drug delivery systems offers a great promise as a modern method of long-acting reversible contraceptives (LARCs) to improve women's health. Unfortunately, there are some scientific challenges associated with the development of these products which are among the major reasons contributing to the availability of relatively few IUS products on the market.

Characterization and in vitro release of minocycline hydrochloride microspheres prepared via coacervation.

Coacervation is a commonly used method for protein and peptide drug microencapsulation using biodegradable or bioresorbable polymers. However, there is a lack of literature focused on microencapsulation of small molecule drugs using coacervation techniques. In addition, the apparatus used for this microencapsulation method has not been well-described.

Polymer source affects in vitro-in vivo correlation of leuprolide acetate PLGA microspheres.

Poly(lactic-co-glycolic acid) PLGA (release controlling excipient) plays a dominant role on the performance of PLGA based long-acting parenterals. These types of drug products typically exhibit complex multi-phasic in vitro/in vivo release/absorption characteristics. In particular, owing to their large size, charged state, and hydrophilicity, peptide loaded microspheres can exhibit more complex release mechanisms.

Assessing microstructural critical quality attributes in PLGA microspheres by FIB-SEM analytics.

The distribution of the active pharmaceutical ingredient (API) within polymer-based controlled release drug products is a critical quality attribute (CQA). It is crucial for the development of such products, to be able to accurately characterize phase distributions in these products to evaluate performance and microstructure (Q3) equivalence. In this study, polymer, API, and porosity distributions in poly(lactic-co-glycolic acid) (PLGA) microspheres were characterized using a combination of focused ion beam scanning electron microscopy (FIB-SEM) and quantitative artificial intelligence (AI) image analytics.

In vitro release testing method development for long-acting injectable suspensions.

Long-acting injectable (LAI) suspensions are complex parenterals intended to control drug release over a duration of weeks to months. Any unpredictive drug release behavior may cause serious side effects. Therefore, it is important to understand the in vitro and in vivo performance, as well as the in vitro-in vivo correlation (IVIVC) of these products.

In vitro-in vivo correlation of PLGA microspheres: Effect of polymer source variation and temperature.

Development of Level A in vitro-in vivo correlations (IVIVCs) remains challenging for complex long-acting parenterals, such as poly(lactic-co-glycolic acid) PLGA microspheres. The nature of the PLGA polymer excipient has a dominant influence on the performance of PLGA microspheres. These microsphere systems typically exhibit multiphasic in vitro/in vivo release/absorption characteristics and may also show interspecies differences (animal model versus human data).

Novel adapter method for in vitro release testing of in situ forming implants.

In situ forming implants are injectable liquid formulations which form solid or semisolid depots following injection. This allows for minimally invasive administration, localized drug delivery, and extended drug release. Unfortunately, this drug delivery strategy lacks standardized in vitro dissolution methods due to the difficulties in recreating implant formation in vitro that is biomimicry and with reproducible and controllable shape and dimensions.

Impact of polymer crosslinking on release mechanisms from long-acting levonorgestrel intrauterine systems.

Polydimethylsiloxane (PDMS) crosslinking density is a critical material attribute of levonorgestrel intrauterine systems (LNG-IUSs) that affects drug release and may have a significant influence on product performance and safety. Accordingly, the objective of the present work was to investigate the impact of PDMS crosslinking on the release mechanisms of LNG-IUSs and thereby achieve better product understanding. To investigate the effect of PDMS crosslinking, LNG-IUSs with varying prepolymer ratios and different mixing conditions were prepared.

Effect of polymer source variation on the properties and performance of risperidone microspheres.

Owing to their inherent heterogeneity, determination of similarity of poly (lactic-co-glycolic acid) (PLGA) polymers is very challenging. The complexity in controlling PLGA characteristics has been recognized as an obstacle to the development of PLGA based long-acting complex drug products (such as microspheres). The objectives of the present study were: (1) to determine minor differences in the physicochemical characteristics (such as inherent viscosity, molecular weight (Mw), monomer ratio (L/G ratio), glass transition temperature (Tg), and blockiness) as well as in the hydrolytic degradation profiles of PLGAs from different sources; and (2) to investigate the impact of PLGAs from different sources on the properties and in vitro performance of risperidone microspheres.

Effect of crosslinking on the physicochemical properties of polydimethylsiloxane-based levonorgestrel intrauterine systems.

Polydimethylsiloxane (PDMS)-based levonorgestrel intrauterine systems (LNG-IUSs) such as Mirena® are long-acting drug-device combination products designed to release LNG for contraceptive purposes up to 6 years. LNG-IUSs consist of a hollow cylindrical drug-PDMS reservoir mounted with a polyethylene frame and covered by an outer PDMS membrane. PDMS is the release-controlling excipient present in both the matrix and the outer membrane.

Effect of polymer source on in vitro drug release from PLGA microspheres.

Determination of the qualitative (Q1) sameness of poly (lactic-co-glycolic acid) (PLGA) polymers can be very challenging due to PLGA being a random copolymer with inherent heterogeneity. Performance variation of PLGA microsphere drug product as a result of altered PLGA characteristics has been recognized as a critical limiting factor in product development. It has been reported that PLGA characteristics and degradation profiles are sensitive to minor differences in the manufacturing and control processes.