Desenvolvimento e caracterização de lipossomas peguilados para veiculação de L-asparaginase / Development and characterization of peg-grafted liposomes for lasparaginase encapsulation

A Leucemia Linfoide Aguda (LLA) é um câncer de maior incidência em crianças, e tem a Lasparaginase (ASNase) como fármaco amplamente utilizado no tratamento dos afetados. A ASNase catalisa a hidrólise do aminoácido L-asparagina (Asn), presente na corrente sanguínea, a ausência do aminoácido no meio extracelular leva à morte células leucêmicas, que necessitam deste aminoácido para as funções celulares. Fatores envolvendo a eficiência do tratamento com ASNase como reações adversas e curta meia-vida, principalmente devido ao reconhecimento pelo sistema imune e degradação por proteases, limitam a sua eficácia. A encapsulação da enzima em lipossomas pode conferir proteção à degradação, melhorar seu perfil farmacocinético e diminuir os efeitos adversos, de forma a melhorar o tratamento da LLA sendo este o objetivo desse trabalho. Lipossomas de DOPC (1,2-dioleoil-sn-glicero-3-fosfocolina) e DMPC (1,2-dimiristoil-snglicero-3-fosfocolina) foram desenvolvidos empregando-se o método de hidratação do filme lipídico e diferentes protocolos de preparo contendo ou não diferentes concentrações de 18:0 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N-[methoxy(polietilenogicol)-2000] (DSPE-PEG). Os lipossomas produzidos foram utilizados para encapsular a ASNase e os sistemas contendo ou não ASNase encapsulada foram caracterizados por espalhamento de luz dinâmico (DLS), potencial zeta, microscopia eletrônica de transmissão (MET) e criomicroscopia de transmissão. Adicionalmente, foram avaliados a taxa de encapsulação e o perfil de permeabilidade das vesículas à L-asparagina. As análises de DLS mostraram que as nanoestruturas formadas empregando-se agitação magnética a partir de sistemas contendo 10% e 20% de DSPE-PEG possuem diâmetro hidrodinâmico menor (~ 25 nm a 60 nm) que os mesmos sistemas sem o fosfolipídio peguilado (~190 nm a 222 nm), demonstrando a relação entre a diminuição do tamanho e o aumento da quantidade de fosfolipídio peguilado e possível formação de estruturas micelares ou bicelares. O emprego de agitação em vórtex para hidratação do filme lipídico, adição do antioxidante -tocoferol e redução da concentração de DSPE-PEG (5% e 10%) levou à formação de sistemas com diâmetro hidrodinâmico maior, sendo esse protocolo e concentrações de PEG definidos como padrão. As análises de MET comprovaram a formação de lipossomas com diâmetro hidrodinâmico semelhante ao observado por DLS; com a utilização da criomicroscopia foi possível observar os lipossomas sem deformações. Os lipossomas de DMPC/DSPE-PEG 10% apresentaram maior permeabilidade à L-asparagina ao longo do tempo e, portanto, poderiam funcionar como nanoreatores, depletando o aminoácido da circulação. Estudos in vitro com células tumorais devem ser realizados e em seguida estudos in vivo, para confirmar este potencial

L-asparaginase (ASNase) is a first-choice drug, combined with other drugs, in therapeutic schemes to treat Acute Lymphoblastic Leukemia (ALL) in children and adolescents. ASNase catalyzes the hydrolysis of L-asparagine (Asn) in the bloodstream; since ALL cells cannot synthesize this amino acid, protein synthesis is impaired leading to leukemic cells death by apoptosis. In spite of its therapeutic importance, treatment with ASNase is associated to side effects, mainly hypersensitivity and immunogenicity. Another drawback refers to degradation by plasma proteases that altogether with immunogenicity shortens the enzyme half-life. Encapsulation of ASNase in liposomes, vesicular nanostructures formed by the self-aggregation of phospholipids, is an attractive alternative that possibly will protect the enzyme from plasma proteases, resulting on better pharmacokinetics profile. In this work, we prepared by thin film hydration liposomal formulations of the phospholipid 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) or 1,2-dimyristoyl-sn-glycero-3- phosphocholine (DMPC) containing or not different concentrations of 18:0 1,2-distearoyl-snglycero-3-phosphoethanolamine-N-[methoxy(polyethylene glycol)-2000] (DSPE-PEG), and encapsulated ASNase by electroporation. The systems containing or not ASNase were analyzed by Dynamic Light Scattering, zeta potential and Electron Microscopy. The encapsulation efficiency and vesicles permeability were also evaluated. According to the DLS analysis, the nanostructures formed by film hydration under magnetic stirring employing 10% or 20% DSPE-PEG presented smaller hydrodynamic diameter (~ 25 nm to 60 nm) than the same systems without the pegylated phospholipid (~ 190 nm to 222 nm), demonstrating the relation between size and the amount of pegylated phospholipid that results in formation of micellar or bicellar structures. The protocol was stabilize by hydration of the lipid film under vortex agitation, addition of the antioxidant - tocopherol and reduction of the concentration of DSPE-PEG (5% and 10%), what altogether led to the formation of nanostructures of higher hydrodynamic diameter and monodisperse systems. TEM analyzes confirmed the formation of liposomes with hydrodynamic diameter similar to that observed by DLS; with the use of cryomicroscopy it was possible to observe the liposomes without deformations. Liposomes of DMPC/DSPE-PEG 10% showed permeability to L-asparagine over time and, therefore, could function as nanoreactors, depleting the circulating amino acid

Conventional treatments and non-PEGylated liposome encapsulated doxorubicin for visceral leishmaniasis: A scoping review

Visceral leishmaniasis (VL), also known as Kala-azar, is caused by Leishmania (L.) donovani complex, which includes L. donovani and L. infantum and is associated with a high death rate as compared to the cutaneous and subcutaneous form. Treatment of VL includes chemotherapeutic agents which are associated with some major hurdles like toxicities, parenteral administration, high cost, parasite resistance and stability. Hence, there is an urgent requirement to develop novel chemotherapeutic agents or repurposing of existing drugs against VL. Developing formulation of new chemical entity for the treatment of VL is laborious, time consuming and associated with huge financial burden. However, screening of existing chemotherapeutic agents is a good alternative to avail cost-effective treatment option for VL. Non-PEGylated liposome encapsulated doxorubicin (Myocet ®) is proposed as an alternative treatment option for VL in this review article. Here, we covered the fundamental aspects of VL, loophole associated with available current treatment strategies and non-PEGylated liposome encapsulated doxorubicin as a novel alternative formulation for treating VL, as this liposomal delivery system of doxorubicin might passively target the intra- cellular regions of macrophage.

An Optimization Of Sterically Stabilized Liposome Using Design Of Experiment Approach

Purpose: Recently, drug delivery system with controlled and targeted drug release at the tumor sites emerged as an attractive option for improving anticancer therapeutics. Advanced Nano therapeutics must not be limited to nano scale but should find their way to target the solid tumor via direct or indirect way. Pegylation on the surface of liposome helps to become liposome as long circulating and indirect or passive targeting to tumor. Purpose of this study is to develop and optimize the critical process parameters which plays important role in the quality pegylated liposome. Design of experiment (DOE) was used to study the impact of critical process variables like hydration temperature, extrusion process temperature, ethanol concentration, drug loading temperature and drug loading time.

Improved anti-tumor efficacy and pharmacokinetics of bufalin via PEGylated liposomes / 中国药理学与毒理学杂志

OBJECTIVE To determine the characterization, anti-tumor efficacy and pharmacokinetics of bufalin- loaded PEGylated liposomes compared with bufalin entity. METHODS Bufalin- loaded PEGylated liposomes and bufalin- loaded liposomes were prepared reproducibly with homogeneous particle size by the combination of thin film evaporation method and high pressure homogenization method. The particle size and zeta potential of the liposomes were determined by dynamic light scattering technique. The direct imaging of morphology of liposomes was charactered by transmission electron microscope. The content of bufalin in liposomes was analysed by HPLC method. The entrapment efficiency and the particle size was applied to assess the stability profile, after storage at 4℃ on day 0, 7, 15, 30 and 90. The in-vitro release behaviours of bufalin from liposomes were conducted using dialysis bag technique at 37℃. In-vitro cytotoxicity studies were carried out using MTT〔3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide〕assay on several kinds of tumor cell lines including SW620, PC-3, MDA-MB-231, A549, U251, U87 and HepG2. In-vivo pharmacokinetic study of bufalin liposomes was evaluated by HPLC method. RESULTS Their mean particle sizes were 127.6 nm and 155.0 nm, mean zeta potentials were 2.24 mV and - 18.5 mV, entrapment efficiencies were 76.31% and 78.40% , respectively. In- vitro release profile revealed that the release of bufalin in bufalin- loaded PEGylated liposomes was slower than that of bufalin-loaded liposomes. The cytotoxicity of blank liposomes has been found within acceptable range, whereas bufalin-loaded PEGylated liposomes showed enhanced cytotoxicity to U251 cells compared with bufalin entity. In-vivo pharmacokinetics indicated that bufalin-loaded PEGylated liposomes could extend eliminate half-life time of bufalin in plasma in rats. CONCLUSION The results suggested that bufalin-loaded PEGylated liposomes improved the solubility and increased the drug concentration in plasma.