Physical Stability and Viscoelastic Properties of Co-Amorphous Ezetimibe/Simvastatin System

Knapik-Kowalczuk, Justyna; Chmiel, Krzysztof; Jurkiewicz, Karolina; Correia, Natália T.; Sawicki, Wiesław; Paluch, Marian

doi:10.3390/ph12010040

Cited by 18 publications

(8 citation statements)

References 54 publications

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“…Simvastatin is obtained by fermentation of Aspergillum terreus , which is a fungi, in the form of inactive lactone, which is further hydrolyzed to active β-hydroxy acid and works as an anti-hyperlipidemic agent by inhibiting HMG-CoA reductase enzyme, which has been well-established in a human clinical trial [ 9 ]. Simvastatin is among the most potent statin and has been listed among the top five frequently prescribed medicines for reducing high cholesterol [ 10 , 11 ]. Apart from its role as anti-hyperlipidemic agent, its pleiotropic effects opens a totally new horizon in medical sciences, suggesting its anti-tumor [ 12 ], anti-cancer [ 13 ], cardio-protective [ 14 ], anti-inflammatory, immune-modulatory, and anti-diabetic potential [ 15 ].…”

Section: Introductionmentioning

confidence: 99%

Highly Responsive Chitosan-Co-Poly (MAA) Nanomatrices through Cross-Linking Polymerization for Solubility Improvement

Saleem

Akhtar

Minhas

et al. 2022

Gels

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In this study, we report the highly responsive chitosan-based chemically cross-linked nanomatrices, a nano-version of hydrogels developed through modified polymerization reaction for solubility improvement of poorly soluble drug simvastatin. The developed nanomatrices were characterized for solubilization efficiency, swelling studies, sol-gel analysis, in vitro drug release studies, DSC, FTIR, XRD, SEM, particle size analysis, and stability studies. An in vivo acute toxicity study was conducted on female Winstor rats, the result of which endorsed the safety and biocompatibility of the system. A porous and fluffy structure was observed under SEM analysis, which supports the great swelling tendency of the system that further governs the in vitro drug release. Zeta sizer analyzed the particle size in the range of 227.8 ± 17.8 nm. Nano sizing and grafting of hydrophilic excipients to the nanomatrices system explains this shift of trend towards the enhancement of solubilization efficiency, and, furthermore, the XRD results confirmed the amorphous nature of the system. FTIR and DSC analysis confirmed the successful grafting and stability to the system. The developed nanomatrices enhanced the release characteristics and solubility of simvastatin significantly and could be an effective technique for solubility and bioavailability enhancement of other BCS class-II drugs. Due to enhanced solubility, efficient method of preparation, excellent physico-chemical features, and rapid and high dissolution and bio-compatibility, the developed nanomatrices may be a promising approach for oral delivery of hydrophobic drugs.

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Section: Introductionmentioning

confidence: 99%

Highly Responsive Chitosan-Co-Poly (MAA) Nanomatrices through Cross-Linking Polymerization for Solubility Improvement

Saleem

Akhtar

Minhas

et al. 2022

Gels

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“…In recent years, co-amorphous drug delivery systems have aroused wide attention for stabilizing neat amorphous drugs and providing solubility/dissolution advantages (such as the faster dissolution rate and enhanced supersaturation ability) over corresponding crystalline and amorphous drugs [ 10 ]. A co-amorphous system is prepared by amorphizing a drug and a small molecule excipient (e.g., glibenclamide-arginine [ 11 ] and griseofulvin-tryptophan [ 12 ]) or a drug and another drug (e.g., docetaxel-bicalutamide [ 13 ] and ezetimibe-simvastatin [ 14 ]), to form a single amorphous phase in a certain stoichiometric ratio. In addition, a co-amorphous drug delivery system has become an effective alternative strategy to overcome the limitations of amorphous solid dispersion (ASD).…”

Section: Introductionmentioning

confidence: 99%

Deaggregation and Crystallization Inhibition by Small Amount of Polymer Addition for a Co-Amorphous Curcumin-Magnolol System

Han

et al. 2021

Pharmaceutics

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Different from previously reported co-amorphous systems, a co-amorphous curcumin-magnolol (CUR-MAG CM) system, as compared with its crystalline counterparts, exhibited decreased dissolution due to its aggregation during dissolution. The main purpose of the present study is to deaggregate CUR-MAG CM to optimize drug dissolution and explore the deaggregation mechanism involved. Herein, a small amount of polymer (HPMC, HPC, and PVP K30) was co-formulated at 5% (w/w) with CUR-MAG CM as ternary co-amorphous systems. The polymer addition changed the surface properties of CUR-MAG CM including improved water wettability enhanced surface free energy, and hence exerted a deaggregating effect. As a result, the ternary co-amorphous systems showed faster and higher dissolution as compared with crystalline CUR/MAG and CUR-MAG CM. In addition, the nucleation and crystal growth of dissolved CUR and MAG molecules were significantly inhibited by the added polymer, maintaining a supersaturated concentration for a long time. Furthermore, polymer addition increased the Tg of CUR-MAG CM, potentially involving molecular interactions and inhibiting molecular mobility, resulting in enhanced physical stability under 25 °C/60% RH and 40 °C/75% RH conditions. Therefore, this study provides a promising strategy to optimize the dissolution and physical stability of co-amorphous systems by deaggregation and crystallization inhibition via adding small amounts of polymers.

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“…Although for e, two distinct carbon signals can be observed for the initial amorphous form, indicative of two predominant orientations, just one signal can be observed in the second MAS period, where the change to the crystalline phase has already begun. Knapik‐Kowalczuk et al [ 27 ] already showed by differential scanning calorimetry (DSC) that quench‐cooled, amorphous EZI has a glass transition at approximately 64°C as the only thermal event, which is approximately 30 K higher than the calibrated sample temperature during MAS. To further exclude temperature as the origin of the observed changes, amorphous EZI was stored in an oven at 40°C for 48 h. Subsequent analysis by XRPD confirmed the amorphicity of the sample (Figure S6).…”

Section: Resultsmentioning

confidence: 99%

“…After 88 days, an additional 1 H‐ 13 C FSLG HECTOR NMR spectrum with the same resolution in the indirect dimension revealed changes in the 1 H NMR chemical shifts. Górniak et al [ 28 ] and Knapik‐Kowalczuk et al [ 27 ] already showed by DSC that EZI has only one endothermic peak at 164°C, [ 28 ] which corresponds to the melting point, making changes due to elevated temperatures unlikely. A comparison of XRPD powder patterns (Figure 6) of EZI before MAS, which should represent the state of the initial 1 H‐ 13 C FSLG HECTOR NMR spectrum, and after MAS, representing the new spectrum, showed no differences in peak positions, so no completely new phase of EZI has formed.…”

Section: Resultsmentioning

confidence: 99%

You cannot fight the pressure: Structural rearrangements of active pharmaceutical ingredients under magic angle spinning

Scheidel

Östreicher

Mark

et al. 2022

Magnetic Reson in Chemistry

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Although solid‐state nuclear magnetic resonance (NMR) is a versatile analytical tool to study polymorphs and phase transitions of pharmaceutical molecules and products, this work summarizes examples of spontaneous and unexpected (and unwanted) structural rearrangements and phase transitions (amorphous‐to‐crystalline and crystalline‐to‐crystalline) under magic angle spinning (MAS) conditions, some of them clearly being due to the pressure experienced by the samples. It is widely known that such changes can often be detected by X‐ray powder diffraction (XRPD); here, the capability of solid‐state NMR experiments with a special focus on 1H‐13C frequency‐switched Lee–Goldburg heteronuclear correlation (FSLG HETCOR)/MAS NMR experiments to detect even subtle changes on a molecular level not observable by conventional 1D NMR experiments or XRPD is presented. Furthermore, it is shown that a polymorphic impurity combined with MAS can induce a crystalline‐to‐crystalline phase transition. This showcases that solid‐state NMR is not always noninvasive and such changes upon MAS should be considered in particular when compounds are studied over longer time spans.

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Physical Stability and Viscoelastic Properties of Co-Amorphous Ezetimibe/Simvastatin System

Cited by 18 publications

References 54 publications

Highly Responsive Chitosan-Co-Poly (MAA) Nanomatrices through Cross-Linking Polymerization for Solubility Improvement

Highly Responsive Chitosan-Co-Poly (MAA) Nanomatrices through Cross-Linking Polymerization for Solubility Improvement

Deaggregation and Crystallization Inhibition by Small Amount of Polymer Addition for a Co-Amorphous Curcumin-Magnolol System

You cannot fight the pressure: Structural rearrangements of active pharmaceutical ingredients under magic angle spinning

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