Molecular Dynamics Simulations to Study Drug Delivery Systems

Albano, Juan M. R.; Paula, Eneida de; Pickholz, Mónica

doi:10.5772/intechopen.75748

Cited by 14 publications

(8 citation statements)

References 73 publications

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“…39 Computer simulations have been extensively used to study many biomolecular interactions such as protein-ligand interactions, protein-protein interactions and membrane transport, including drug delivery systems. [41][42][43][44][45][46] MD simulations have also been used to investigate the binding mechanisms of cordycepin and many protein targets, for example uric acid transporter 1 (URAT1) associated with anti-hyperuricemic effect 47 and Cdk-2 in cervical cancer. 48 Atomistic insight into binding properties can be used as guidance for the design of new potent proteins inhibitors.…”

Section: Introductionmentioning

confidence: 99%

In silico and in vitro design of cordycepin encapsulation in liposomes for colon cancer treatment

et al. 2021

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Section: Introductionmentioning

confidence: 99%

In silico and in vitro design of cordycepin encapsulation in liposomes for colon cancer treatment

et al. 2021

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“…The understanding of the encapsulation process on a molecular-level could be very helpful to design an effective drug carrier. Molecular dynamics (MD) simulation is a very powerful tool to understand a number of biomolecular processes and could help to develop and improve drug delivery systems [ 17 ]. MD simulations are particularly valuable in addressing issues that are difficult to explore with laboratory measurements.…”

Section: Introductionmentioning

confidence: 99%

Influence of Terpene Type on the Release from an O/W Nanoemulsion: Experimental and Theoretical Studies

Miastkowska

Śliwa

2020

Molecules

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The interaction between a drug molecule and its carrier’s components is an important factor which influences the drug release profile. For this purpose, molecular dynamics (MD) may be the in silico tool which can help to understand the mechanism of drug loading/release. The aim of this work is to explain the effect of interactions between different types of terpenes, namely perillyl alcohol, forskolin, ursolic acid, and the nanoemulsion droplet core, on the release by means of experimental and theoretical studies. The basic nanoemulsion was composed of caprylic/capric triglyceride as the oil phase, polysorbate 80 as the emulsifier, and water. The in vitro release tests from a terpene-loaded nanoemulsion were carried out to determine the release profiles. The behavior of terpenoids in the nanoemulsion was also theoretically investigated using the molecular dynamics method. The forskolin-loaded nanoemulsion showed the highest percentage of drug release (almost 80% w/w) in contrast to ursolic acid and perillyl alcohol-loaded nanoemulsions (about 53% w/w and 19% w/w, respectively). The results confirmed that the kinetic model of release was terpene-type dependent. The zero-order model was the best to describe the ursolic acid release profile, while the forskolin and the perillyl alcohol followed a first-order and Higuchi model, respectively. Molecular dynamics simulations, especially energetical analysis, confirmed that the driving force of terpenes diffusion from nanoemulsion interior was their interaction energy with a surfactant.

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“…MD is an invaluable tool in the hands of protein allostery researchers [44]. MD experiments simulate biological protein movement at various levels of theory, for which molecular mechanical approximations (coupled to Newton's second law of motion) [271] are the most common for relatively large solvated protein systems. At the junction between the quantum and coarse-grained atomic models, all-atom MD simulations provide a good trade-off between accuracy and speed for conformational sampling, producing quality spatiotemporal data associated to protein action.…”

Section: Conformational Sampling Molecular Dynamicsmentioning

confidence: 99%

Integrated Computational Approaches and Tools for Allosteric Drug Discovery

Amamuddy

Veldman

Manyumwa

et al. 2020

IJMS

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Understanding molecular mechanisms underlying the complexity of allosteric regulation in proteins has attracted considerable attention in drug discovery due to the benefits and versatility of allosteric modulators in providing desirable selectivity against protein targets while minimizing toxicity and other side effects. The proliferation of novel computational approaches for predicting ligand–protein interactions and binding using dynamic and network-centric perspectives has led to new insights into allosteric mechanisms and facilitated computer-based discovery of allosteric drugs. Although no absolute method of experimental and in silico allosteric drug/site discovery exists, current methods are still being improved. As such, the critical analysis and integration of established approaches into robust, reproducible, and customizable computational pipelines with experimental feedback could make allosteric drug discovery more efficient and reliable. In this article, we review computational approaches for allosteric drug discovery and discuss how these tools can be utilized to develop consensus workflows for in silico identification of allosteric sites and modulators with some applications to pathogen resistance and precision medicine. The emerging realization that allosteric modulators can exploit distinct regulatory mechanisms and can provide access to targeted modulation of protein activities could open opportunities for probing biological processes and in silico design of drug combinations with improved therapeutic indices and a broad range of activities.

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Molecular Dynamics Simulations to Study Drug Delivery Systems

Cited by 14 publications

References 73 publications

In silico and in vitro design of cordycepin encapsulation in liposomes for colon cancer treatment

In silico and in vitro design of cordycepin encapsulation in liposomes for colon cancer treatment

Influence of Terpene Type on the Release from an O/W Nanoemulsion: Experimental and Theoretical Studies

Integrated Computational Approaches and Tools for Allosteric Drug Discovery

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