This study aimed to investigate the effects of different process parameters on the physical properties, in vitro dissolution rate, and short and long-term stability of diclofenac potassium(DFP) granules and capsules...This study aimed to investigate the effects of different process parameters on the physical properties, in vitro dissolution rate, and short and long-term stability of diclofenac potassium(DFP) granules and capsules. DFP granules exhibited low total amounts of impurities when prepared through the wet granulation method using a granulating solvent with a low water/ethanol ratio. The impurities of the wet DFP mass dried at 70 ℃ were higher than those dried at 50 ℃ or 60 ℃. DFP granules were stable under strong light exposure during preparation. DFP granules prepared using a granulating solvent with a 1:4 water/ethanol ratio had a relatively smaller particle size and higher angle of repose than those prepared using granulating solvents with other water/ethanol ratios. The dissolution rate of DFP capsules prepared using four different water/ethanol ratios was less than 2% after 10 min of dissolution and increased to 95% within 30 min of dissolution. The total amount of drug impurities of DFP capsules prepared using a granulating solvent with 1:4 water/ethanol ratio was considerably lower than those of DFP capsules prepared using a granulating solvent with a 1:0 water/ethanol solvent ratio. Regardless of the water/ethanol ratio, the capsules showed poor stability when exposed to high temperature(60 ℃) and strong light(4500±500 Lux) for 10 days, but were relatively stable at high humidity(92.5% RH). The results of the long-term stability(25±2 ℃ and 60%±10% relative humidity) study showed that DFP granules were more stable than DFP capsules, and were stable for 12 months. The type of encapsulating material did not affect the 2-month stability of DFP. DFP granules are sensitive to granulating solvent and drying temperature and DFP capsules should be stored away from high temperature and strong light.展开更多
Intracellular Ca2+ is vital for cell physiology.Disruption of Ca2+ homeostasis contributes to human diseases such as heart failure,neuron-degeneration,and diabetes.To ensure an effective intracellular Ca2+ dynamics,va...Intracellular Ca2+ is vital for cell physiology.Disruption of Ca2+ homeostasis contributes to human diseases such as heart failure,neuron-degeneration,and diabetes.To ensure an effective intracellular Ca2+ dynamics,various Ca2+ transport proteins localized in different cellular regions have to work in coordination.The central role of mitochondrial Ca2+ transport mechanisms in responding to physiological Ca2+ pulses in cytosol is to take up Ca2+ for regulating energy production and shaping the amplitude and duration of Ca2+ transients in various micro-domains.Since the discovery that isolated mitochondria can take up large quantities of Ca2+ approximately 5 decades ago,extensive studies have been focused on the functional characterization and implication of ion channels that dictate Ca2+ transport across the inner mitochondrial membrane.The mitochondrial Ca2+ uptake sensitive to non-specific inhibitors ruthenium red and Ru360 has long been considered as the activity of mitochondrial Ca2+ uniporter(MCU) .The general consensus is that MCU is dominantly or exclusively responsible for the mitochondrial Ca2+ influx.Since multiple Ca2+ influx mechanisms(e.g.L-,T-,and N-type Ca2+ channel) have their unique functions in the plasma membrane,it is plausible that mitochondrial inner membrane has more than just MCU to decode complex intracellular Ca2+ signaling in various cell types.During the last decade,four molecular identities related to mitochondrial Ca2+ influx mechanisms have been identified.These are mitochondrial ryanodine receptor,mitochondrial uncoupling proteins,LETM1(Ca2+ /H+ exchanger) ,and MCU and its Ca2+ sensing regulatory subunit MICU1.Here,we briefly review recent progress in these and other reported mitochondrial Ca2+ influx pathways and their differences in kinetics,Ca2+ dependence,and pharmacological characteristics.Their potential physiological and pathological implications are also discussed.展开更多
Chalcopyrite ternary CulnS2 semiconductor nanocry stals have been synthesized via a facile one-pot chemical approach by using oleylamine and oleic acid as solvents. The as-prepared CuInS2 nanocrystals have been chara...Chalcopyrite ternary CulnS2 semiconductor nanocry stals have been synthesized via a facile one-pot chemical approach by using oleylamine and oleic acid as solvents. The as-prepared CuInS2 nanocrystals have been characterized by instrumental analyses such as X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), transmission electron microscopy (TEM)/high-resolution TEM (HRTEM), energy-dispersive X-ray spectroscopy (EDS), UV-vis absorption spectroscopy (UV-vis) and photoluminescence (PL) spectroscopy. The particle sizes of the CuInS2 nanocrystals could be tuned from 2 to 10 nm by simply varying reaction conditions. Oleylamine, which acted as both a reductant and an effective capping agent, plays an important role in the size-controlled synthesis of CulnS2 nanocrystals. Based on a series of comparative experiments under different reaction conditions, the probable formation mechanism of CulnS2 nanocrystals has been proposed. Furthermore, the UV-vis absorption and PL emission spectra of the chalcopyrite CulnS2 nanocrystals have been found to be adjustable in the range of 527-815 nm and 625-800 rim, respectively, indicating their potential application in photovoltaic devices.展开更多
基金National Natural Science Foundation of China(Grant No.81373333,81311140267)
文摘This study aimed to investigate the effects of different process parameters on the physical properties, in vitro dissolution rate, and short and long-term stability of diclofenac potassium(DFP) granules and capsules. DFP granules exhibited low total amounts of impurities when prepared through the wet granulation method using a granulating solvent with a low water/ethanol ratio. The impurities of the wet DFP mass dried at 70 ℃ were higher than those dried at 50 ℃ or 60 ℃. DFP granules were stable under strong light exposure during preparation. DFP granules prepared using a granulating solvent with a 1:4 water/ethanol ratio had a relatively smaller particle size and higher angle of repose than those prepared using granulating solvents with other water/ethanol ratios. The dissolution rate of DFP capsules prepared using four different water/ethanol ratios was less than 2% after 10 min of dissolution and increased to 95% within 30 min of dissolution. The total amount of drug impurities of DFP capsules prepared using a granulating solvent with 1:4 water/ethanol ratio was considerably lower than those of DFP capsules prepared using a granulating solvent with a 1:0 water/ethanol solvent ratio. Regardless of the water/ethanol ratio, the capsules showed poor stability when exposed to high temperature(60 ℃) and strong light(4500±500 Lux) for 10 days, but were relatively stable at high humidity(92.5% RH). The results of the long-term stability(25±2 ℃ and 60%±10% relative humidity) study showed that DFP granules were more stable than DFP capsules, and were stable for 12 months. The type of encapsulating material did not affect the 2-month stability of DFP. DFP granules are sensitive to granulating solvent and drying temperature and DFP capsules should be stored away from high temperature and strong light.
基金supported by NIH grants(Grant Nos.HL-033333 and HL093671)to Shey-Shing Sheu
文摘Intracellular Ca2+ is vital for cell physiology.Disruption of Ca2+ homeostasis contributes to human diseases such as heart failure,neuron-degeneration,and diabetes.To ensure an effective intracellular Ca2+ dynamics,various Ca2+ transport proteins localized in different cellular regions have to work in coordination.The central role of mitochondrial Ca2+ transport mechanisms in responding to physiological Ca2+ pulses in cytosol is to take up Ca2+ for regulating energy production and shaping the amplitude and duration of Ca2+ transients in various micro-domains.Since the discovery that isolated mitochondria can take up large quantities of Ca2+ approximately 5 decades ago,extensive studies have been focused on the functional characterization and implication of ion channels that dictate Ca2+ transport across the inner mitochondrial membrane.The mitochondrial Ca2+ uptake sensitive to non-specific inhibitors ruthenium red and Ru360 has long been considered as the activity of mitochondrial Ca2+ uniporter(MCU) .The general consensus is that MCU is dominantly or exclusively responsible for the mitochondrial Ca2+ influx.Since multiple Ca2+ influx mechanisms(e.g.L-,T-,and N-type Ca2+ channel) have their unique functions in the plasma membrane,it is plausible that mitochondrial inner membrane has more than just MCU to decode complex intracellular Ca2+ signaling in various cell types.During the last decade,four molecular identities related to mitochondrial Ca2+ influx mechanisms have been identified.These are mitochondrial ryanodine receptor,mitochondrial uncoupling proteins,LETM1(Ca2+ /H+ exchanger) ,and MCU and its Ca2+ sensing regulatory subunit MICU1.Here,we briefly review recent progress in these and other reported mitochondrial Ca2+ influx pathways and their differences in kinetics,Ca2+ dependence,and pharmacological characteristics.Their potential physiological and pathological implications are also discussed.
基金supported by the National Basic Research Program of China(2009CB220003)the National High Technology Research and Development Progress of China (2009AA03Z233)+1 种基金MOE Innovation team (IRT0927)the Fundamental Research Funds for the Central Universities
文摘Chalcopyrite ternary CulnS2 semiconductor nanocry stals have been synthesized via a facile one-pot chemical approach by using oleylamine and oleic acid as solvents. The as-prepared CuInS2 nanocrystals have been characterized by instrumental analyses such as X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), transmission electron microscopy (TEM)/high-resolution TEM (HRTEM), energy-dispersive X-ray spectroscopy (EDS), UV-vis absorption spectroscopy (UV-vis) and photoluminescence (PL) spectroscopy. The particle sizes of the CuInS2 nanocrystals could be tuned from 2 to 10 nm by simply varying reaction conditions. Oleylamine, which acted as both a reductant and an effective capping agent, plays an important role in the size-controlled synthesis of CulnS2 nanocrystals. Based on a series of comparative experiments under different reaction conditions, the probable formation mechanism of CulnS2 nanocrystals has been proposed. Furthermore, the UV-vis absorption and PL emission spectra of the chalcopyrite CulnS2 nanocrystals have been found to be adjustable in the range of 527-815 nm and 625-800 rim, respectively, indicating their potential application in photovoltaic devices.
