Surfactant Effects on Lipid-Based Vesicles Properties

Bnyan, Ruba; Khan, Iftikhar; Ehtezazi, Touraj; Saleem, Imran; Gordon, Sarah; O’Neill, Francis; Roberts, Matthew

doi:10.1016/j.xphs.2018.01.005

Cited by 164 publications

(129 citation statements)

References 98 publications

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“…For compound 1 A , DLS results depended on concentration: it was impossible to obtain good correlograms below the cac, whereas particles with variable, concentration‐dependent sizes in a range from 97.4±42.5 nm (at 500 μ m ) to 244.7±147.3 nm (at 120 μ m ) and good polydispersity values (PDI ≈0.17 and 0.27, respectively) were observed over that threshold (Figure A). This inverse relationship between size and polydispersity values with concentration is common for vesicles from both ionic and neutral surfactants and, together with the found size range and microscopy observations described below, suggests the possible vesicular nature of the 1 A assemblies. Compound 1 T , in contrast, showed narrow signals in the same size range (Figure B); that is, from 86.0±35.2 nm (at 500 μ m ) to 148.8±63.9 nm (at 10 μ m ), with low polydispersity values (PDI ≈0.16 and 0.18, respectively) for the whole range of concentrations at which this dinucleolipid self‐assembles (from 10 μ m 1 T ).…”

Section: Resultsmentioning

confidence: 99%

Programmed Recognition between Complementary Dinucleolipids To Control the Self‐Assembly of Lipidic Amphiphiles

Morales-Reina

Giri

Leclercq

et al. 2020

Chemistry A European J

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One of the major goals in systems chemistry is to create molecular assemblies with emergent properties that are characteristic of life. An interesting approach toward this goal is based on mergingd ifferent biological building blocks into synthetic systems with properties arising from the combination of their molecular components. The covalentl inkage of nucleic acids (or their constituents:n ucleotides,n ucleosides and nucleobases) with lipids in the same hybrid molecule leads, for example, to the so-called nucleolipids. Herein, we describen ucleolipids with av ery short sequence of two nucleobases per lipid, which, in combination with hydrophobic effectsp romoted by the lipophilic chain, allow controlo ft he self-assembly of lipidic amphiphiles to be achieved. The presentw ork describes as pectroscopic and microscopy study of the structural features and dynamic selfassembly of dinucleolipids that contain adenine or thymine moieties, either pure or in mixtures. This approach leads to different self-assembled nanostructures, which include spherical, rectangulara nd fibrillara ssemblies, as af unction of the sequence of nucleobases and chiral effects of the nucleolipidsinvolved.W ealso show evidencethat the resulting architectures can encapsulate hydrophobic molecules,r evealing their potential as drug delivery vehicles or as compartmentstoh ost interesting chemistries in their interior.

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Section: Resultsmentioning

confidence: 99%

Programmed Recognition between Complementary Dinucleolipids To Control the Self‐Assembly of Lipidic Amphiphiles

Morales-Reina

Giri

Leclercq

et al. 2020

Chemistry A European J

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“…Therefore, natural and synthetic phospholipids (EPC and DMPC) were investigated in this study. Additionally, it was reported that the surfactant type and concentration can also affect transfersome size and %EE . For this reason, three surfactants (EA) were used in this DOE in three different percentages (Table ).…”

Section: Resultsmentioning

confidence: 99%

“…Additionally, it was reported that the surfactant type and concentration can also affect transfersome size and % EE. [18] For this reason, three surfactants (EA) were used in this DOE in three different percentages ( Table 2). Lidocaine-loaded transfersomes were prepared according to the designed experiments (Table 3).…”

Section: Transfersome Optimisation and Taguchi Doe Analysismentioning

confidence: 99%

“…Novel transfersomes loaded with LA such as lidocaine and intended to be a sustained‐release delivery system could be a better approach to improve patient compliance and achieve the required level of anaesthesia. However, the properties of drug loaded transfersomes usually vary with several parameters such as the nature of lipid and EA component, the concentration of each component, and the preparation process parameters . Although previous studies have attempted to find the optimum composition of transfersomes with some desired properties, a new optimisation study was required since both the drug and sustained‐release transfersomes have not been reported in the literature to date.…”

Section: Introductionmentioning

confidence: 99%

“…However, the properties of drug loaded transfersomes usually vary with several parameters such as the nature of lipid and EA component, the concentration of each component, and the preparation process parameters. [18] Although previous studies have attempted to find the optimum composition of transfersomes with some desired properties, [19,20] a new optimisation study was required since both the drug and sustained-release transfersomes have not been reported in the literature to date. Optimisation of properties such as size and entrapment efficiency (%EE) was essential in order to obtain transfersomes that could produce the required level of anaesthesia without any systemic side effects.…”

Section: Introductionmentioning

confidence: 99%

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Formulation and optimisation of novel transfersomes for sustained release of local anaesthetic

Bnyan

Khan

Ehtezazi

et al. 2019

Journal of Pharmacy and Pharmacology

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Objective To investigate the effect of formulation parameters on the preparation of transfersomes as sustained‐release delivery systems for lidocaine and to develop and validate a new high‐performance liquid chromatography (HPLC) method for analysis. Method Taguchi design of experiment (DOE) was used to optimise lidocaine‐loaded transfersomes in terms of phospholipid, edge activator (EA) and phospholipid : EA ratio. Transfersomes were characterised for size, polydispersity index (PDI), charge and entrapment efficiency (%EE). A HPLC method for lidocaine quantification was optimised and validated using a mobile phase of 30%v/v PBS (0.01 m) : 70%v/v Acetonitrile at a flow rate of 1 ml/min, detected at 255 nm with retention time of 2.84 min. The release of lidocaine from selected samples was assessed in vitro. Key findings Transfersomes were 200 nm in size, with PDI ~ 0.3. HPLC method was valid for linearity (0.1–2 mg/ml, R2 0.9999), accuracy, intermediate precision and repeatability according to ICH guidelines. The %EE was between 44% and 56% and dependent on the formulation parameters. Taguchi DOE showed the effect of factors was in the rank order : lipid : EA ratio ˃ EA type ˃ lipid type. Optimised transfersomes sustained the release of lidocaine over 24 h. Conclusion Sustained‐release, lidocaine‐loaded transfersomes were successfully formulated and optimised using a DOE approach, and a new HPLC method for lidocaine analysis was developed and validated.

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Preparation and Physicochemical Properties of a Cysteine Derivative‐Loaded Deformable Liposomes in Hydrogel for Enhancing Whitening Effects

Jeong

Kim

et al. 2018

Euro J Lipid Sci & Tech

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Whitening materials cannot easily cross the skin barrier (stratum corneum) to reach melanocytes in the basal layer for inhibiting melanin production. This study aims to construct a novel deformable liposome using polyglyceryl‐3‐methylglucose distearate as an edge activator and a hydrogel containing hyaluronic acid (HA) and hydroxyethyl cellulose (HEC), as well as to investigate the synergistic effect of this system on the delivery of a cysteine derivative, methyl‐2‐acetylamino‐3‐(4‐hydroxyl‐3,5‐dimethoxybenzoylthio)propanoate (MP) as a whitening agent. The optimized deformable liposome (DL2) contains 10% edge activator and has a particle size of 78.2 ± 2.7 nm, a zeta potential of −29.9 ± 1.8 mV, a polydispersity index of 0.248, and an entrapment efficiency of 90.7 ± 1.7%. MP‐loaded DL2 has higher stability and deformability than DL2 without MP, as well as exerting a higher whitening effect than that observe with MP alone. In addition, MP‐loaded DL2 is incorporated into a hydrogel in a dual drug‐delivery system and the stability after hydrogel incorporation is evaluated. In Franz cells, the MP‐loaded deformable liposome‐hydrogel complex shows the highest skin permeation and penetration of MP. Practical Applications: In general, it is very difficult for whitening agents to penetrate a skin layer for reducing skin pigmentation. It is important to transfer whitening agents to the basal layer without causing physical damage to the skin. Deformable liposomes containing 10% polyglyceryl‐3‐methylglucose distearate in a hydrogel complex maximize the skin permeation of a cysteine derivative as a whitening agent. This finding indicates that the deformable liposome‐hydrogel complex is a potential delivery system for treatment of skin hyperpigmentation. The penetration mechanism of drugs in the skin by deformable liposome‐hydrogel complexes is as follows: Hydrogel hydrates stratum corneum to secure the route of drugs or nanocarrier permeation. polyglyceryl‐3‐methylglucose distearate as an edge activator enhances the fluidity of the stratum corneum lipid layer and the deformability of liposome. The edge activator‐based deformable liposomes pass through the stratum corneum stably.

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Surfactant Effects on Lipid-Based Vesicles Properties

Cited by 164 publications

References 98 publications

Programmed Recognition between Complementary Dinucleolipids To Control the Self‐Assembly of Lipidic Amphiphiles

Programmed Recognition between Complementary Dinucleolipids To Control the Self‐Assembly of Lipidic Amphiphiles

Formulation and optimisation of novel transfersomes for sustained release of local anaesthetic

Preparation and Physicochemical Properties of a Cysteine Derivative‐Loaded Deformable Liposomes in Hydrogel for Enhancing Whitening Effects

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