Orthogonal Gelations to Synthesize Core–Shell Hydrogels Loaded with Nanoemulsion‐Templated Drug Nanoparticles for Versatile Oral Drug Delivery

Attia, Lucas; Chen, Liang-Hsun; Doyle, Patrick S.

doi:10.1002/adhm.202301667

Cited by 4 publications

(3 citation statements)

References 120 publications

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“…Using this workflow, we simulate the effect of surfactant weight fraction at experimentally realistic compositions on the crystal structure and dynamics. We corroborate our simulation results using the bottom-up nanocrystallization method developed in our group − to relate the excipient composition and interfacial structure to the experimentally observed extent of crystallinity. These are the first simulations that directly characterize structural changes in a drug crystal as a result of excipient surface composition and relate experimental extent of crystallinity to molecular-level structure.…”

Section: Introductionsupporting

confidence: 83%

“…Such bottom-up methods tend to blur the boundaries between drug substance and drug product manufacturing by including excipients in the crystallization process . For example, one such bottom-up process, flash nanoprecipitation, produces polymer-coated drug nanoparticles through antisolvent precipitation in a turbulent mixing device. , Another approach developed in our research group crystallizes drug nanoparticles by encapsulating and then evaporating drug-loaded nanodroplets inside hydrogel matrices, enabling high drug-loaded formulations of hydrophobic APIs with controllable drug release. − In parallel, formulating hydrophobic drugs into ASDs has also improved the dissolution and bioavailability for many drugs . ASDs exploit the ability of a polymer matrix to stabilize amorphous aggregates of drug molecules and inhibit crystallization, which promotes rapid drug release during delivery .…”

Section: Introductionmentioning

confidence: 99%

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Surfactant–Polymer Complexation and Competition on Drug Nanocrystal Surfaces Control Crystallinity

Attia,

Nguyen,

Gokhale

et al. 2024

ACS Appl. Mater. Interfaces

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Nanosizing drug crystals has emerged as a successful approach to enabling oral bioavailability, as increasing drug crystal surface area improves dissolution kinetics and effective solubility. Recently, bottom-up methods have been developed to directly assemble nanosized crystals by leveraging polymer and surfactant excipients during crystallization to control crystal size, morphology, and structure. However, while significant research has investigated how polymers and other single additives inhibit or promote crystallization in pharmaceutical systems, there is little work studying the mechanistic interactions of multiple excipients on drug crystal structure and the extent of crystallinity, which can influence formulation performance. This study explores how the structure and crystallinity of a model hydrophobic drug crystal, fenofibrate, change as a result of competitive interfacial chemisorption between common nonionic surfactants (polysorbate 80 and sorbitan monooleate) and a surfaceactive polymer excipient (methylcellulose). Classical molecular dynamics simulations highlight how key intermolecular interactions, including surfactant−polymer complexation and surfactant screening of the crystal surface, modify the resulting crystal structure. In parallel, experiments generating drug nanocrystals in hydrogel thin films validate that drug crystallinity increases with an increasing weight fraction of surfactant. Simulation results reveal a connection between accelerated dynamics in the bulk crystal and the experimentally measured extent of crystallinity. To our knowledge, these are the first simulations that directly characterize structural changes in a drug crystal as a result of excipient surface composition and relate the experimental extent of crystallinity to structural changes in the molecular crystal. Our approach provides a mechanistic understanding of crystallinity in nanocrystallization, which can expand the range of orally deliverable small molecule therapies.

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Section: Introductionsupporting

confidence: 83%

Section: Introductionmentioning

confidence: 99%

Surfactant–Polymer Complexation and Competition on Drug Nanocrystal Surfaces Control Crystallinity

Attia,

Nguyen,

Gokhale

et al. 2024

ACS Appl. Mater. Interfaces

Self Cite

View full text Add to dashboard Cite

show abstract

“…They encapsulate the drug in their matrix, which allows the administration of the drug orally, topically, or parenterally, with specific, targeted properties with controlled or delayed release. This formulation increases the bioavailability of hydrophobic drugs and enables combining several compounds in one hydrogel matrix [25][26][27][28]. Considering the above-discussed properties of hydrogels, these matrices can be used as a promising delivery system for low soluble hydrophobic therapeutic agents such as curcumin.…”

Section: Hydrogelsmentioning

confidence: 99%

Wondrous Yellow Molecule: Are Hydrogels a Successful Strategy to Overcome the Limitations of Curcumin?

Stachowiak,

Mlynarczyk,

Dlugaszewska

2024

Molecules

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Curcumin is a natural compound with a great pharmaceutical potential that involves anticancer, anti-inflammatory, antioxidant, and neuroprotective activity. Unfortunately, its low bioavailability, instability, and poor water solubility significantly deteriorate its clinical use. Many attempts have been made to overcome this issue, and encapsulating curcumin in a hydrogel matrix may improve those properties. Hydrogel formulation is used in many drug delivery forms, including classic types and novel forms such as self-assembly systems or responsive to external factors. Reviewed studies confirmed better properties of hydrogel-stabilized curcumin in comparison to pure compound. The main enhanced characteristics were chemical stability, bioavailability, and water solubility, which enabled these systems to be tested for various diseases. These formulations were evaluated for wound healing properties, effectiveness in treating skin diseases, and anticancer and regenerative activity. Hydrogel formulation significantly improved biopharmaceutical properties, opening the opportunity to finally see curcumin as a clinically approved substance and unravel its therapeutic potential.

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Stimuli‐Responsive Polymers for Engineered Emulsions

Rajbanshi,

Hilton,

Dreiss

et al. 2024

Macromol. Rapid Commun.

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Emulsions are complex. Dispersing two immiscible phases, thus expanding an interface, requires effort to achieve and the resultant dispersion is thermodynamically unstable, driving the system toward coalescence. Furthermore, physical instabilities, including creaming, arise due to presence of dispersed droplets of different densities to a continuous phase. Emulsions allow the formulation of oils, can act as vehicles to solubilize both hydrophilic and lipophilic molecules, and can be tailored to desirable rheological profiles, including “gel‐like” behavior and shear thinning. The usefulness of emulsions can be further expanded by imparting stimuli‐responsive or “smart” behaviors by inclusion of a stimuli‐responsive emulsifier, polymer or surfactant. This enables manipulation like gelation, breaking, or aggregation, by external triggers such as pH, temperature, or salt concentration changes. This platform generates functional materials for pharmaceuticals, cosmetics, oil recovery, and colloid engineering, combining both smart behaviors and intrinsic benefit of emulsions. However, with increased functionality comes greater complexity. This review focuses on the use of stimuli‐responsive polymers for the generation of smart emulsions, motivated by the great adaptability of polymers for this application and their efficacy as steric stabilizers. Stimuli‐responsive emulsions are described according to the trigger used to provide the reader with an overview of progress in this field.

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Orthogonal Gelations to Synthesize Core–Shell Hydrogels Loaded with Nanoemulsion‐Templated Drug Nanoparticles for Versatile Oral Drug Delivery

Cited by 4 publications

References 120 publications

Surfactant–Polymer Complexation and Competition on Drug Nanocrystal Surfaces Control Crystallinity

Surfactant–Polymer Complexation and Competition on Drug Nanocrystal Surfaces Control Crystallinity

Wondrous Yellow Molecule: Are Hydrogels a Successful Strategy to Overcome the Limitations of Curcumin?

Stimuli‐Responsive Polymers for Engineered Emulsions

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