The Role of Cavitation in Liposome Formation

Richardson, Eric S.; Pitt, William G.; Woodbury, Dixon J.

doi:10.1529/biophysj.107.104042

Cited by 86 publications

(78 citation statements)

References 32 publications

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“…In fact, incorporation of cholesterol increases rigidity of the bilayer membrane, and consequently improves the physical stability of many niosomal systems [26]. Additionally, cholesterol eliminates the phase transition temperature peak of the vesicles, thereby stabilizes the bilayer structure, strengthens the bilayer structures and diminishes bilayer micro fluidity [27], a situation that would interfere with the size reduction during sonication step. The vesicular membranes are more flexible at low concentration of cholesterol, resultantly; they are more sensitive to the ultrasound waves, resulting in smaller size.…”

Section: Effect Of Cholesterol Concentration On Particle Sizementioning

confidence: 99%

Effect of Formulation and Processing Variables on Dexamethasone Entrapment and Release of Niosomes

2015

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Multilamellar niosomes entrapping Dexamethasone (Dex) were prepared by thin film hydration, sonication, respectively. The influence of different processing variables (sonication time, temperature) and formulation variable (cholesterol content) on Dex entrapment efficiency % (EE) was demonstrated. Also, the Dex release from the prepared niosomes in phosphate buffer (pH 7.4) was illustrated. Results indicated that cholesterol increased or decreased the noisome size and EE % depending on its concentration within the formulae. The maximum loading efficiency was 29.2 % when the span 60:cholesterol molar ratio was 100:50 and the hydrating step was conducted by 30 min sonication. Increasing sonication time also increased and then decreased the EE % of Dex into niosomes. Finally, results indicated that in vitro release profiles of Dex from all niosome formulations is an apparently biphasic release process and 5-15 % of drug released from niosomes after 8 h incubation in buffer, depending on the type of niosome.

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Section: Effect Of Cholesterol Concentration On Particle Sizementioning

confidence: 99%

Effect of Formulation and Processing Variables on Dexamethasone Entrapment and Release of Niosomes

2015

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“…Large shear forces and shock waves created by the cavitation effect generate holes in the membrane (34). This phenomenon is known as the 'sonoporation effect', and allows molecules outside the membrane to penetrate into the cells, and may subsequently improve the efficiency of delivery of therapeutic molecules into cells (35,36). Marmottant and Hilgenfeldt (37) suggest that low intensity ultrasonic irradiation, which induces vacuole vibration and microsound flow, may have the potential to alter cell membrane permeability.…”

Section: Discussionmentioning

confidence: 99%

Upregulation of ULK1 expression in PC-3 cells following tumor protein P53 transfection by sonoporation

et al. 2015

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Abstract. The aim of the present study was to investigate whether ultrasound combined with microbubbles was able to enhance liposome-mediated transfection of genes into human prostate cancer cells, and to examine the association between autophagy and tumor protein P53 (P53). An MTT assay was used to evaluate cell viability, while flow cytometry and fluorescence microscopy were used to measure gene transfection efficiency. Autophagy was observed using transmission electron microscopy. Reverse transcription-polymerase chain reaction (RT-PCR) and western blot analysis were used to assess the expression of autophagy-associated genes. The results of the present study revealed that cell viability was significantly reduced following successfully enhanced transfection of P53 by ultrasound combined with microbubbles. In addition, serine/threonine-protein kinase ULK1 levels were simultaneously upregulated. Castration-resistant prostate cancer is difficult to treat and is investigated in the present study. P53 has a significant role in a number of key biological functions, including DNA repair, apoptosis, cell cycle, autophagy, senescence and angiogenesis. Prior to the present study, to the best of our knowledge, increased transfection efficiency and reduced side effects have been difficult to achieve. Ultrasound is considered to be a 'gentle' technique that may be able to achieve increased transfection efficiency and reduced side effects. The results of the present study highlight a potential novel therapeutic strategy for the treatment of prostate cancer.

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“…A modificação de tamanho de vesículas poliméricas pode ser explicada pelo mesmo fenômeno descrito para vesículas lipídicas, o qual se sustenta no fato de que a oscilação das bolhas cria uma pressão local resultando na quebra das vesículas maiores em fragmentos que se reorganizam em vesículas menores. 53 A…”

Section: Métodos De Preparounclassified

Polimerossomos versus lipossomos: a evolução da "Bala Mágica"

Apolinário¹,

Pachioni-Vasconcelos²,

Pessoa³

et al. 2017

Quim. Nova

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publicado na web em 15/05/2017 POLYMERSOMES VERSUS LIPOSOMES: THE "MAGIC BULLET" EVOLUTION. Polymeric vesicles known as polymersomes are formed by the self-assemble of amphiphilic block copolymers and have structural organization similar to liposomes. However, polymersomes present higher physicochemical stability and structure versatility due to their polymeric nature. In this review we describe the main aspects related to the structure and applications of these systems for drug delivery.Keywords: drug delivery; polymersomes; liposomes; amphiphilic block-copolymers; self-aggregated nanostructures. INTRODUÇÃOAs pesquisas com sistemas de liberação de fármacos e biofár-macos a partir de nanoestruturas têm revolucionado as ciências farmacêuticas no mundo todo.1,2 Estes nanocarreadores (NC) têm propriedades peculiares relacionadas ao tamanho em escala nanométrica e área superficial aumentada, o que lhes confere potencial para modular características farmacocinéticas e farmacodinâmicas de fármacos. Portanto, são capazes de melhorar a estabilidade in vitro e in vivo de fármacos, prolongar o tempo de circulação sanguínea e permitir a liberação controlada e direcionada. 3,4 Devido às vantagens dos NC, a cada dia estudos descrevem novas possibilidades de aperfeiçoar ainda mais estes sistemas e percebe-se uma evolução constante no campo da nanotecnologia aplicada a produtos farmacêuticos, especialmente na oncologia. As pesquisas relatam NC amplamente usados como nanopartículas poliméricas, nanopartículas lipídicas sólidas, nanopartículas metálicas e lipossomos (LP), com diferentes abordagens referentes à composição, inovações na técnica de produção e alternativas para liberação sítio-dirigida, de modo que haja aprimoramento funcional do produto final. 5-9Um exemplo bastante atual de inovação em nanocarreadores são as vesículas poliméricas, descritas inicialmente em 1981 por Kunitake e colaboradores 10 e em 1995 estudadas com maior embasamento físico-químico por Zhang & Eisenberg.11 Posteriormente, essas vesículas foram denominadas polimerossomos (PL) por Discher e colaboradores, 12 uma vez que apresentam organização estrutural semelhante aos LP. PL podem ser conceituados como nanocarreadores supramoleculares poliméricos com estrutura vesicular. Enquanto LP são vesículas de interior aquoso compostas por uma membrana lipí-dica, os PL, que também apresentam interior aquoso, são compostos por uma membrana de copolímeros anfifílicos.Para compreender a importância dos PL, é válido reforçar que são morfologicamente análogos aos LP, os quais estão entre os NC mais empregados no campo farmacêutico e foram relatados pioneiramente nos anos 60 por Bangham e seus colaboradores, que descreveram estruturas vesiculares organizadas em bicamadas originadas por fosfolipídeos em soluções aquosas. 13 Após estudos iniciais com LPs, percebeu-se que estes nanocarreadores poderiam se encaixar no conceito proposto por Paul Ehrlich conhecido por "Bala Mágica" ou do inglês "Magic Bullet", conceito descrito em um artigo publicado 15 No entanto, a inst...

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The Role of Cavitation in Liposome Formation

Cited by 86 publications

References 32 publications

Effect of Formulation and Processing Variables on Dexamethasone Entrapment and Release of Niosomes

Effect of Formulation and Processing Variables on Dexamethasone Entrapment and Release of Niosomes

Upregulation of ULK1 expression in PC-3 cells following tumor protein P53 transfection by sonoporation

Polimerossomos versus lipossomos: a evolução da "Bala Mágica"

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