用微流控装置以高时间分辨率测量温度敏感脂质体的药物释放动力学。
Drug release kinetics of temperature sensitive liposomes measured at high-temporal resolution with a millifluidic device.
机构信息
a Department of Bioengineering , George Mason University , Fairfax , VA , USA.
b BTG International Inc , West Conshohocken , PA , USA.
出版信息
Int J Hyperthermia. 2018 Sep;34(6):786-794. doi: 10.1080/02656736.2017.1412504. Epub 2017 Dec 28.
PURPOSE
Current release assays have inadequate temporal resolution ( ∼ 10 s) to characterise temperature sensitive liposomes (TSL) designed for intravascular triggered drug release, where release within the first few seconds is relevant for drug delivery.
MATERIALS AND METHODS
We developed a novel release assay based on a millifluidic device. A 500 µm capillary tube was heated by a temperature-controlled Peltier element. A TSL solution encapsulating a fluorescent compound was pumped through the tube, producing a fluorescence gradient along the tube due to TSL release. Release kinetics were measured by analysing fluorescence images of the tube. We measured three TSL formulations: traditional TSL (DPPC:DSPC:DSPE-PEF2000,80:15:5), MSPC-LTSL (DPPC:MSPC:DSPE-PEG2000,85:10:5) and MPPC-LTSL (DPPC:MMPC:PEF2000,86:10:4). TSL were loaded with either carboxyfluorescein (CF), Calcein, tetramethylrhodamine (TMR) or doxorubicin (Dox). TSL were diluted in one of the four buffers: phosphate buffered saline (PBS), 10% bovine serum albumin (BSA) solution, foetal bovine serum (FBS) or human plasma. Release was measured between 37-45 °C.
RESULTS
The millifluidic device allowed measurement of release kinetics within the first few seconds at ∼5 ms temporal resolution. Dox had the fastest release and highest release %, followed by CF, Calcein and TMR. Of the four buffers, release was fastest in human plasma, followed by FBS, BSA and PBS.
CONCLUSIONS
The millifluidic device allows measurement of TSL release at unprecedented temporal resolution, thus allowing adequate characterisation of TSL release at time scales relevant for intravascular triggered drug release. The type of buffer and encapsulated compound significantly affect release kinetics and need to be considered when designing and evaluating novel TSL-drug combinations.
目的
目前的释放分析方法的时间分辨率不足(约 10 秒),无法对设计用于血管内触发药物释放的温度敏感脂质体(TSL)进行特征描述,而在最初几秒钟内的释放对于药物输送是相关的。
材料和方法
我们开发了一种基于微流控装置的新型释放分析方法。一个 500μm 的毛细管通过控温的 Peltier 元件加热。含有荧光化合物的 TSL 溶液通过管泵送,由于 TSL 释放,在管中产生荧光梯度。通过分析管的荧光图像来测量释放动力学。我们测量了三种 TSL 制剂:传统 TSL(DPPC:DSPC:DSPE-PEF2000,80:15:5)、MSPC-LTSL(DPPC:MSPC:DSPE-PEG2000,85:10:5)和 MPPC-LTSL(DPPC:MMPC:PEF2000,86:10:4)。TSL 负载的化合物有羧基荧光素(CF)、钙黄绿素、四甲基罗丹明(TMR)或阿霉素(Dox)。TSL 分别稀释于四种缓冲液中:磷酸盐缓冲盐水(PBS)、10%牛血清白蛋白(BSA)溶液、胎牛血清(FBS)或人血浆。在 37-45°C 之间测量释放。
结果
微流控装置允许在 ∼5 ms 的时间分辨率下测量最初几秒钟内的释放动力学。Dox 的释放最快,释放率和释放百分比最高,其次是 CF、钙黄绿素和 TMR。在这四种缓冲液中,在人血浆中释放最快,其次是 FBS、BSA 和 PBS。
结论
微流控装置允许以前所未有的时间分辨率测量 TSL 的释放,从而能够在与血管内触发药物释放相关的时间尺度上对 TSL 释放进行充分的特征描述。缓冲液的类型和包封的化合物对释放动力学有显著影响,在设计和评估新型 TSL-药物组合时需要考虑。
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