Improved dissolution of Kaempferia parviflora extract for oral administration by preparing solid dispersion via solvent evaporation

Kaempferia parviflora, a plant in the family Zingiberaceae, has been used in Thai traditional medicines for treating hypertension and promoting longevity with good health and wellbeing. However, its limited aqueous solubility and low dissolution restrict its bioavailability.The aim of the study was therefore to improve the dissolution rate of K. parviflora extracted with dichloromethane(KPD) by solid dispersions. Different water-soluble polymers were applied to improve dissolution of KPD. The solid dispersions in different ratios were prepared by solvent evaporation method. Only hydroxypropyl methylcellulose(HPMC) and polyvinyl alcohol-polyethylene glycol grafted copolymer(PVA-co-PEG) could be used to produce homogeneous, powdered solid dispersions. Physical characterization by scanning electron microscopy, hot stage microscopy, differential scanning calorimetry and powder X-ray diffractometry, in comparison with corresponding physical mixtures, showed the changes in solid state during the formation of solid dispersions. Dissolution of a selected marker,5,7,4′-trimethoxyflavone(TMF), from KPD/HPMC and KPD/PVA-co-PEG solid dispersions was significantly improved, compared with pure KPD. The dissolution enhancement by solid dispersion was influenced by both type and content of polymers. The stability of KPD/HPMC and KPD/PVA-co-PEG solid dispersions was also good after 6-month storage in both longterm and accelerated conditions. These results identified that the KPD/HPMC and KPD/PVAco-PEG solid dispersions were an effective new approach for pharmaceutical application of K. parviflora.

An efficient preparation of porous polymeric microspheres by solvent evaporation in foam phase

This paper reports an efficient method of preparing porous polymeric microspheres by solvent evaporation in foam phase,in which phase separation between polymer and porogen occurs in foam phase instead of that in water phase by using the traditional solvent eva poration method.The method provides outstanding features,including being time-saving,of high-yield and able for continuous production,in which formation of porous polymeric microspheres finished within 3 min with a high production yield up to approximate 95 wt% and the process was able to be developed into a continuous process for production of porous polymeric microspheres.It was also universal to non-crosslinked polymers since the method is a development on the traditional emulsion solvent evaporation method.The new method is efficient and can be used potentially on the industrial scale for continuous production of porous polymeric microsphere s.

Thermodynamic solvation of a series of homologous α-amino acids in non-aqueous mixture of ethylene-glycol and N,N-dimethyl formamide

Standard free energies (ΔG0t(i) ) and entropies (ΔS0t(i)) of transfer of some homologous α-amino acids viz. glycine (gly), dl-alanine (ala), dl-α-amino butyric acid (aba) and dl-nor-valine (nor-val) from protic ethylene glycol (EG) to dipolar aprotic N,N-dimethyl formamide (DMF) have been evaluated from solubility measure-ments at five equidistant temperatures i.e from 15 to 350C. The observed ΔG0t(i) and TΔS0t(i) Vs composition profiles are complicated because of the various interaction effects. The chemical effects of the transfer Gibbs energies (ΔG0t.ch(i)) and entropies of transfer (ΔS0t.ch(i)) have been obtained after elimination of cavity effect, estimated by the scaled particle theory and dipole-dipole interaction effects, estimated by the use of Keesom-orientation expression. The chemical contributions of transfer energetics of homologous α-amino acids are guided by the composite effects of increased dispersion interaction, basicity and decreased acidity, hydrogen bonding effects and solvophobic solvation of ethylene glycol and N, N-dimethyl formamide mixed solvent as compared to that of reference solvent (ethylene glycol).

SAFE-GC-MS/O法比较18种浓香型天然香辛料香气活性成分差异分析

采用溶剂萃取法,结合溶剂辅助蒸发(SAFE)装置,分离富集了18种浓香型天然香辛料的挥发性香气活性成分,使用气相色谱-质谱/嗅闻联用(GC-MS/O)对香气活性成分进行了定性定量分析,依据主成分分析法分析其含量差异。结果表明,在检测出的192种香气活性成分中,烯烃类化合物种类最多,为46种,其次为醇类39种、酯类29种、酮类22种、醛类20种、酚类13种、烷烃9种、酸类8种、醚类5种、含硫化合物1种。18种浓香型天然香辛料可依据主成分分析法分为4类:(1)以茴香脑为主的龙蒿、八角茴香、莳萝和小茴香;(2)以反式-肉桂醛、桉叶油醇为主的阴香;(3)以4-烯丙基苯乙酸酯和丁香酚为主的丁香、以桉叶油醇为主的小豆蔻、以乙酸桂酯为主的大清桂、以合成右旋龙脑、百里香酚和香芹酚为主的百里香、以反式-肉桂醛和丙位依兰油烯为主的桂皮、以左旋香芹酮为主的葛缕子、以黄樟素为主的肉豆蔻和以3-甲基苯甲酸乙酯为主的芹菜籽;(4)以芳樟醇和香叶醇为主的芫荽籽、以芳樟醇和4-烯丙基苯甲醚为主的甜罗勒、以乙酸芳樟酯为主的牛至、以肉豆蔻醚为主的多香果和以甲基丁香酚为主的香豆蔻。

基于SAFE法分析市售小磨香油的关键风味成分

以市售小磨香油为研究对象,采用溶剂辅助风味蒸发萃取(SAFE)法萃取其挥发性风味成分,利用三重四级杆气相色谱-质谱联用进行半定量分析,结合相对气味活度值(ROAV)进行关键风味成分贡献度分析。结果表明:从市售小磨香油中共鉴定出107种挥发性风味成分,其中35种挥发性风味成分(ROAV≥0.01)具有典型的风味特征贡献,包括4种硫化物、5种酚类、10种吡嗪类、4种呋喃类、3种醛类、4种噻唑类、2种吡咯类、2种噻吩类和1种吲哚,使小磨香油呈现卷心菜味、鱼腥味、硫磺味、烟熏味、爆米花味、油香和烤芝麻味。14种ROAV≥0.10的风味成分(乙酰基吡嗪、2-呋喃甲醇、2,3-二甲基-吡嗪、2,3,5-三甲基吡嗪、二甲基二硫醚、二甲基三硫醚、甲基糠基二硫醚、硫醇酸甲酯、4-乙烯基-2-甲氧基苯酚、2-甲氧基苯酚、己醛、2-乙基-6-甲基吡嗪、2-甲基-3-呋喃硫醇和3-乙基-2,5-二甲基-吡嗪)被确认为小磨香油的关键风味成分。综上,采用该方法确定小磨香油的关键风味成分,不仅可扩充小磨香油的风味数据库,还可为芝麻油风味品质评价及品质调控提供重要的物质基础。

耐高温阻硅垢荧光缓释微球的制备与缓释特征

缓释型阻垢剂常用来延长阻垢剂作用距离和时间,但在地热开采等高温循环水中,常规缓释技术释放速度过快导致效果不佳。为增强高温下的缓释效果,本文以耐热材料聚苯乙烯为壁材,以固相/油相/水相溶剂挥发法制备新型阻垢缓释微球,优选了芯材和乳化剂,探究了制备工艺,并利用荧光技术测试了缓释效率和阻垢效果。结果表明:硅藻土和十六烷基磺酸钠分别适宜用作固相吸附材料和乳化剂;乳化剂浓度为2%,芯材浓度为50 mg/mL,搅拌速度300 r/min为最佳制备条件。制备的微球静态释放时间长达100 h,动态释放时间超过20 h, 20 h阻垢率50%以上。本成果有望为高温循环水提供新型缓释阻垢技术。

包覆低共熔溶剂的聚苯乙烯微胶囊吸附Li^(+)的性能研究

为实现绿色、低成本从海水中提锂的目标,采用同轴共流微流体技术结合溶剂挥发法制备包覆有低共熔溶剂(甲基三辛基氯化铵/癸酸)的聚苯乙烯微胶囊。所制备的微胶囊颗粒呈均一的球形。将该微胶囊用作萃取Li^(+)吸附剂,系统研究了吸附时间、吸附温度、溶液pH、初始锂浓度和固液比对Li^(+)吸附量和萃取率的影响。结果表明在吸附Li^(+)水溶液时,微胶囊对Li^(+)的最大吸附量为32 mg·g^(-1)。碱性条件时微胶囊对模拟海水中的Li^(+)吸附分配比为10.22 L·g^(-1)。

电气石微胶囊的制备及性能研究

以乙基纤维素为壁材,电气石粉体为芯材,采用乳化-溶剂蒸发法制备电气石微胶囊,通过单因素实验分析了工艺条件对电气石微胶囊负载量和粒径的影响,利用扫描电子显微镜、傅里叶变换红外光谱仪、热分析仪和空气离子计数器等对微胶囊的微观形貌、结构、热稳定性、负载量以及负氧离子释放性能进行表征。结果表明:在芯壁质量比为1∶2、乳化剂含量为连续相溶剂的0.5%、搅拌速度为400r/min、溶剂挥发温度为57℃时,微胶囊负载量达到46.2%(质量分数),平均粒径为20.3μm;电气石粉体被乙基纤维素有效包覆,电气石微胶囊呈规则的球状,表面光滑,壳层上分布着大量的孔道。热重分析表明电气石微胶囊在200℃后才有明显的质量损失,热稳定性较好。负氧离子动态释放量大约15d达到平衡稳定状态,释放量约为850个/cm^(3)。

溶剂辅助风味蒸发结合气相色谱-质谱/嗅闻法分析20种辛香型香辛料香气活性成分

为研究辛香型香辛料的香气活性成分,推进其加工和应用标准化进程,本实验利用溶剂辅助风味蒸发法分离提取香辛料的挥发性香气成分,结合气相色谱-质谱/嗅闻技术对20种辛香型香辛料的香气活性成分进行定性定量分析。基于嗅闻分析,在香辛料样品中共嗅闻到203种香气活性化合物(香气稀释因子≥9),主要由醇类、含硫类化合物、烯烃类、酯类、酮类、醛类、酚类、酸类组成,不同种类香辛料的香气活性成分含量存在差异。进一步进行主成分分析,所有样品可以很好地划分为3组。大蒜、大葱、小葱、洋葱的香气活性成分以含硫类化合物为主,其余香辛料的香气活性成分以烯烃类、醇类、酚类、酮类为主。含硫类香气活性成分在大蒜中检出含量最高,为3 484 777.68μg/kg,在大蒜中检出多种具有葱属植物风味特征的二硫醚、三硫醚等含硫类化合物;烯烃类香气活性成分在姜中检出含量最高,为72 847 224.14μg/kg,检出姜的主要香气成分α-姜烯、β-倍半水芹烯等;醇类香气活性成分和酮类香气活性成分在野薄荷中检出含量较高,分别为284 886.09μg/kg和196 167.66μg/kg,检出野薄荷的特征香气成分薄荷醇、香芹酮;醛类香气活性成分在木姜子中检出含量较高,为469 242.68μg/kg,检出木姜子的主要香气成分柠檬醛、香茅醛等。本研究解析了辛香型香料的关键香气成分,为其精深加工提供一定的理论依据。

亲水高分子涂层制备过程中水对涂层润滑性能的影响

利用一种通用的两步浸涂+光固化工艺在聚氨酯片材表面制备聚乙烯吡咯烷酮亲水润滑涂层,制备过程中环境湿度(水汽)及涂层溶液含水量对制得涂层的润滑性能会产生一定影响。相较于较低湿度(30%RH)的制备条件,高湿度下(70%RH)制得的涂层其摩擦系数显著下降,平均可从0.183降至0.035。同等湿度下,改变顶层涂层溶液中水的占比,涂层的润滑性能同样呈现出较大差异。在30%RH时,随着顶涂溶液含水量的增加,制得涂层的摩擦系数平均由含水量0wt%时的0.183逐渐降至20wt%时的0.043。当溶剂中水的占比超过一定量时,涂层的润滑性能将向相反方向变化。不同条件下制得涂层的外观形貌以及顶涂溶剂蒸发过程揭示了涂层制备时水对涂层润滑性能的可能影响。

炸鸡翅营养组分变化及关键香气成分分析

将鸡翅裹面并采用棕榈油炸,分析炸制前后鸡翅中脂肪酸和氨基酸组成变化及炸鸡翅的关键香气成分。研究发现,油炸后鸡翅肉中脂肪酸和氨基酸总含量均升高,尤其必需氨基酸与总氨基酸的比值及必需氨基酸与非必需氨基酸的比值达到了43.23%和76.16%,营养指标提高。以二氯甲烷为溶剂,采用溶剂辅助蒸发提取炸鸡翅样品中的挥发性风味物质,结合气相色谱-质谱分析鉴定出80种挥发性化合物,频率法气相色谱-嗅闻分析鉴定出51种风味物质是油炸鸡翅的气味活性化合物,G C-O检测的强势气味化合物(NIF≥55%)为2,5-二甲基-吡嗪、己醛、3-甲硫基丙醛、3-乙基-2,5-二甲基-吡嗪、2-甲基丁醛、(E)-2-壬烯醛、γ-丁内酯等36种,对这些化合物计算OAV值,确定炸鸡翅关键香气化合物(OAV≥1)25种,分别为2-甲基-3-呋喃硫醇、双(2-甲基-3-呋喃基)二硫、(E,E)-2,4-癸二烯醛、2-乙基-3,5-二甲基-吡嗪、1-辛烯-3-酮、(E)-2-癸烯醛、(E,E)-2,4-壬二烯醛、2-甲基丁醛、(E)-2-壬烯醛、3-乙基-2,5-二甲基-吡嗪、3-甲硫基丙醛、糠醛、己醛、辛醛、二甲基二硫醚、壬醛、癸醛、苯乙醛、2-戊基呋喃、2-丁酮、2,5-二甲基-吡嗪、(E)-2-庚烯醛、2,3,5-三甲基-吡嗪、2-甲基-吡嗪、乙偶姻25种。希望研究结果可为鸡肉的烹饪加工和肉味香精的研制提供理论参考。

聚丁二酸-共-对苯二甲酸丁二醇酯/氧化镁复合薄膜的制备及性能

以聚丁二酸-共-对苯二甲酸丁二醇酯(PBST)为基体,纳米氧化镁(MgO NPs)为抗菌剂,通过溶剂挥发法制备了PBST/MgO纳米复合薄膜,并探讨了复合薄膜在食品包装中的应用。研究了MgO NPs对纳米复合薄膜的机械性能、水蒸汽透过率(WVP)、氧气透过率(OTR)和紫外阻隔性能的影响。结果表明:MgO NPs的加入改善了PBST基体的力学性能和阻隔性能。与PBST薄膜相比,复合膜的拉伸强度和断裂伸长率分别提高了43.7%和32.2%,水蒸汽透过率和氧气透过率分别降低了28.1%和23.6%,并具有良好的紫外阻隔性能。当MgO NPs质量含量为5%时,复合膜的性能最佳。

基于电子鼻和溶剂辅助风味蒸发-气相色谱-质谱联用技术分析调味小龙虾挥发性风味特征差异

为探究调味小龙虾风味特征差异,该文以市售常见调味小龙虾为研究对象,采用电子鼻结合溶剂辅助风味蒸发-气相色谱-质谱联用(solvent-assisted flavor evaporation-gas chromatography-mass spectrometry,SAFE-GC-MS)技术对其挥发性风味成分进行分析。结果表明,电子鼻能够较好地区分不同调味小龙虾,W1W(对无机硫化物灵敏)、W1S(对甲基类灵敏)和W2W(对芳香成分、有机硫化物灵敏)是区分调味小龙虾风味的主要传感器。8个调味小龙虾样品中共检出127种挥发性风味物质,通过相对气味活度值(relative odor activity value,ROAV)法确定了15种关键风味物质和10种修饰性风味物质,其中麻辣小龙虾主要关键风味物质为芳樟醇、桉叶油醇、丁香酚和D-柠檬烯,十三香小龙虾主要关键风味物质主要为丁香酚、芳樟醇、桉叶油醇、壬醛和β-蒎烯,而蒜蓉小龙虾主要关键风味物质为2,4-二叔丁基苯酚、L-石竹烯、壬醛、苯乙醛、2-甲基-2-丁烯醛和二烯丙基硫醚等。该研究结果可为调味小龙虾风味统一、产品开发和生产提供理论参考。

乳化溶剂蒸发法在递送体系中的应用

将生物活性物质载入递送体系可以改善其水溶性、稳定性和生物利用度,便于在食品、药品和化妆品等领域应用。乳化溶剂蒸发法是一种常见的制备活性物质递送载体的方法,具有使用条件温和,易于操作和放大,溶剂残留较低等优点。本文简要介绍乳化溶剂蒸发法,综述材料的选择和制备过程对所制载体的影响以及该法在制备活性物质递送体系中的应用研究进展,旨在推动乳化溶剂蒸发法的深入研究和实际应用。

外水相组成对醋酸戈舍瑞林PLGA微球理化性质的影响

目的 采用W/O/W和O/W乳化溶剂挥发法制备醋酸戈舍瑞林PLGA微球,考察在外部水相中加入不同浓度的氯化钠和甘露醇对所制备微球理化性质的影响。方法 醋酸戈舍瑞林PLGA微球采用W/O/W和O/W乳化溶剂挥发法制备,以微球的表面形态、内部形态、粒径、载药量、体外累计释放行为、结构和晶型来评价不同浓度的添加剂对两种制备方法所制得微球的影响。结果 采用W/O/W制备的微球增加外水相中氯化钠的浓度,微球载药量增加、粒径减小、突释量降低、微球表面及内部孔洞减少;增加外水相中甘露醇的浓度,微球载药量增加、粒径减小,突释量降低、微球表面孔洞减少,内部孔洞未减少;O/W法制备的微球增加水相中氯化钠和甘露醇的浓度,微球载药量增加、粒径减小、突释量降低、微球表面及内部孔洞减少。结论 通过增加外部水相中添加剂的浓度,有效改善了醋酸戈舍瑞林PLGA微球的结构和性质。

7-羟乙基白杨素聚乳酸-羟基乙酸共聚物纳米粒的制备及体外释放评价

目的:制备和评价7-羟乙基白杨素(7-HEC)聚乳酸-羟基乙酸共聚物(PLGA)纳米粒。方法:采用乳化溶剂挥发法制备7-HEC/PLGA纳米粒,以粒径、多分散系数(PDI)、包封率、载药量及Zeta电位为评价指标,通过单因素考察结合Box-Behnken响应面法优化处方。采用甘露醇作为冻干保护剂制备冻干粉,对最优处方制备的7-HEC/PLGA纳米粒进行表征及体外释放研究。结果:经Box-Behnken响应面法优化后的最优处方为:药载比2.12∶20,油水体积比1∶14.7,乳化剂为2.72%大豆磷脂。最优处方条件制备的7-HEC/PLGA纳米粒的平均粒径为(240.28±0.96)nm、PDI为0.25±0.69、包封率为(75.74±0.80)%、载药量为(6.98±0.83)%、电位为(-18.17±0.17)mV。体外释放48 h内累积释放度达到50%以上。结论:优化所得处方工艺稳定、操作简便。所得7-HEC/PLGA纳米粒粒度均匀,包封率较高。相对于7-HEC原料药,7-HEC/PLGA纳米粒的溶出度显著提高。

Omni-functional simultaneous interfacial treatment for enhancing stability and outgassing suppression of lithium-ion batteries

Ni-rich layered oxides in lithium-ion batteries have problems with gas generation and electrochemical performance reduction due to residual lithium's reaction on the surface with the electrolyte.To address this issue,in this study,the Acid solvent evaporation(AsE)method has been proposed as a potential method to remove residual lithium while promoting the formation of a new LiNO_(3)-derived coating layer on the cathode surface.The reduction of residual lithium using the ASE method and the construction of a LiNO_(3)-derived coating layer suppresses gas evolution caused by the side effects of the electrolyte,improves electrochemical performance,and improves thermal stability by facilitating the smooth movement of lithium ions.Furthermore,the structural stability and resistance change due to the LiNO_(3)-derived coating layer effects is guaranteed through cycling and DCIR of the pouch cell.As a result,compared to Pristine,the capacity retention of coin cells increased by 8%after 100 cycles,and pouch cells increased by 25%after 160 cycles.In addition,after cycling the pouch cell,CO_(2) gas has significantly reduced by about 30%compared to Pristine using gas chromatography.The ASE method effectively forms a robust LiNO_(3)-derived coating layer on the cathode active material,which helps minimize electrolyte reactivity,suppress ,CO_(2) emissions,enhance surface structure stability,improve thermal stability,and improveoverallbatteryperformance.

Preparation of 20 (S)-protopanaxadiol PLGA Nanoparticles

[Objectives]To prepare 20(S)-protopanaxadiol PLGA nanoparticles(20(S)-PPD-PLGA-NPs).[Methods]20(S)-PPD-PLGA-NPs were prepared by emulsion solvent evaporation method,and the optimal formulation was screened by Box-Behnken experiment with particle size and drug loading as the indicators through single factor experiment,and the drug release in vitro was carried out.[Results]The average diameter of the nanoparticles was(119.60±2.29)nm and the polydispersity index was(0.12±0.02),the size was uniform.The encapsulation efficiency and drug loading of protopanaxadiol were(87.99±1.29)%and(14.86±0.25)%,respectively.[Conclusions]The 20(S)-PPD-PLGA-NPs were successfully prepared by emulsion solvent evaporation method,and the 20(S)-PPD-PLGA-NPs had good stability,to lay a foundation for the study of 20(S)-PPD-PLGA-NPs in vitro and in vivo.

单因素结合Box-Benhnken响应曲面法优化载青蒿素聚乳酸-羟基乙酸共聚物纳米粒制备工艺

本研究优化包载青蒿素(artemisinin,ART)聚乳酸-羟基乙酸共聚物(poly(lactic-co-glycolic acid),PLGA)纳米粒(PLGA-ART-NPs)的最优工艺。首先采用乳化-溶剂法制备纳米粒,以单因素实验确定乳化剂种类(聚乙烯醇、吐温80、泊洛沙姆)、乳化剂浓度、水-油两相比例及载体-药物比例对粒径、载药量、包封率的影响;以载药量为评价指标,通过Box-Benhnken响应面法,进一步优化PLGA-ART-NPs制备工艺。结果表明聚乙烯醇乳化效果最好,以乳化剂浓度、水-油两相比例、载体-药物比例为影响因素,最优处方确定为:乳化剂浓度为0.017 g/mL,水-油两相比例为18∶1(V/V),载体-药物比例为10∶1(W/W)。以最优处方制备的纳米粒载药量为(4.43±0.22)%,zeta电位为-28.28±2.17 mV,表明本文优化后的处方工艺条件稳定,重复性良好,可行性高,制得的纳米溶液稳定性良好。

HPLC-GC联用技术的原理与仪器发展

LC与GC的联用技术在预分离、富集等方面有着重要的应用,其有效减轻了样品的制备难度。相较于其他技术,LC在分离功率方面具有更高的效率,并且可以将样品制备全自动集成到GC中。本文讨论了HPLC-GC联用技术的优点,并对此技术的溶剂蒸发、接口等技术进行了概述。