• Journal of Pharmaceutical Investigation
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• 제38권5호
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• pp.335-342
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• 2008

The bioequivalence of two carbamazepine preparations was conducted. The in vivo bioequivalence study in 20 healthy male Korean volunteers was designed by using a single dose, randomized, 2-period crossover with a 3-weeks washout period between the doses. Prior to the in vivo study, an in vitro comparative dissolution test was performed by the paddle and basket method as described in the bioequivalence guidance of the Korea Food and Drug Administration (KFDA). Based on the similar dissolution pattern between two preparations in the dissolution test, the two formulations are demonstrated to be pharmaceutically equivalent. In addition, in vivo bioequivalence test was used to reconfirm the in vitro dissolution results. In the in vivo bioequivalence study, the plasma concentrations of carbamazepine up to 144 h after the administration were determined using a validated HPLC method with UV detection and the bioequivalence between the two drug products was assessed by statistical analysis of the log transformed mean ratios of $C_{max}$, $AUC_{0-t}$ and $AUC_{0-\infty}$. The mean maximum concentration ($C_{max}$) of the test and reference were found to be $1467.0{\pm}335.8\;ng/mL$ and $1465.9{\pm}310.3\;ng/mL$, respectively. The 90% confidence intervals (C.I.) of $C_{max}$ were in the range from 0.95 to 1.05. As for the $AUC_{0-t}$ and $AUC_{0-\infty}$, test values were $110027.1{\pm}27786.4\;ng/mL{\cdpt}h$, $128807.0{\pm}34563.2\;ng/mL{\cdot}h$ and $105473.6{\pm}26496.2\;ng/mL{\cdot}h$, $125448.5{\pm}35975.5\;ng/mL{\cdot}h$, respectively. The 90% C.I. of $AUC_{0-t}$ were 0.97 to 1.10 and of $AUC_{0-\infty}$, 0.99 to 1.09 and thus were within the log 0.8-log 1.25 interval proposed by the KFDA. A two-way ANOVA showed no significant difference between the two formulations. Based on these statistical analysis, it was concluded that the test formulation is bioequivalent to the reference.

• KSBB Journal
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• 제11권4호
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• pp.476-480
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• 1996

Using Pseudomonas sp. B3, identified and isolated from nature, wastewater containing phenol was treated in a continuous stirred tank reactor and its reaction characteristics were studied. Average concentrations of phenol and COD in effluents were 1.5mg/L and 124mg/L at 0.059h-1 dilution rate, respectively. At the dilution rate higher than 0.063h-1, phenol and COD increased abruptly to 19mg/L and 318mg/L. At the dilution rate higher than 0.059h-1, biomass concentration suddenly decreased and was "washed out". Biomass concentration was 150mg/L at a dilution rate of 0.067h-1. Maximum biomass production rate was 15.98mg/L$.$h at a dilution rate of 0.067h-1. When dilution rate increased above 0.059h-1, effluent phenol concentration abruptly increased and biomass production rate decreased. Maximum cell growth rate(${\mu}$max) and Michaelis-Mentens kinetic constant(Ks) were 0.074h-1 and 0.424mg/L, respectively. From the above result low phenol concentration can be expected at a maximum dilution rate, but reactor becomes unstable due to phenol inhibition.

• KSBB Journal
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• 제17권1호
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• pp.73-79
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• 2002

본 연구에서는 C. ljungdahlii를 이용하여 일산화탄소로부터 에탄올 생성 방법을 최적화하였다. 먼저 Clostridium ljungdahlii ATCC 55383을 이용하여 일산화탄소 소비속도에 대한 kinetic model과 그에 따른 여러 가지 상수값을 계산하기 위한 실험을 수행하였다. 이 결과 일 산화탄소 소비속도 data에 Michaelis Menten식이 잘 적용됨을 알수 있었고 기울기 값 $K_m/V_{max}$ max 및 y-절편값 $1/V_{max}$로부터 구한 $V_{max}$는 37.14 mmol/L-hr-O.D. 그리고 $K_{m}$은 0.9516 atm임을 알 수 있었다. C. ljungdahlii에서의 ethanol의 생성에 미치는 pH와 질소원의 영향을 실험한 결과 세포성장에는 pH 5.5와 YE첨가가 에탄올 생성에는 pH 4~4.5, ammonium solution $(NH_4Cl+(NH_4)_2SO_4$)첨가가 필요한 것으로 확인되었다. 따라서 pH 5.5와 YE 0.5%에서 C. ljungdahlii를 배양한 후 pH 4.5로 shift하고 ammonium solution을 계속 첨가한 경우 세포농도 0.D. 0.25에서 약 3.6 g/L의 에탄올 생성을 얻었으며 이것은 pH 및 질소원 shift가 없는 경우에 비하여 약 20배 이상 에탄을 생성양이 증가된 수치이다. 이를 바탕으로 pH shift 후 N source로서 ammonium solution을 지속적으로 공급하여 주면서 fermenter를 이용한 일산화탄소로부터 에탄을 최적화를 수행하였고 이 결과 최대 specific ethanol production rate 0.49 g ethanol/L.hr.O.D.를 얻을 수 있었으며 생성된 최종 에탄을 농도는 25 g ethanol/L에 달하였다. 이 결과를 이용하여 높은 세포농도를 얻기 위하여 세포성장에 도움을 주는 탄소원 실험을 수행하였고 이 결과 glucose를 이용한 세포성장후 일산화탄소로 전환하는 방법을 fermenter에 적용하여 pH 5.5, 400 rpm 조건에서 glucose를 feeding하여 O.D. 3.4가지 자라게 한 후 ammonium solution을 첨가하여 주면서 일산화탄소를 소비하는 시점가지 약 10시간 동안 CO adaptation을 실시하여 일산화탄소의 소비속도가 충분한 속도에 달했을 때 pH를 5.5에서 4.5로 낮추어 주었고 그 후 간헐적으로 ammonium solution을 feeding한 결과 얻어진 최종 에탄을 생성량은 45 g/L 이었다. 특히 약60시간 이내에 45 g/L 정도의 ethanol을 생성 함으로써 0.75 g ethanol/L.hr의 ethanol 생산성을 확보 할 수 있었다. 또한 C. ljungdahlii이 에탄을 내성을 실험한 결과 약 50 g/L 정도의 에탄올에는 큰 성장 장애를 받지 않는 것으로 나타나 이 균주를 이용한 산업체 부생가스로부터의 에탄을 생산 가능성을 더하여 주고 있다. 현재 본 연구진에 의하여 C. ljungdahlii를 이용하여 long term operation시의 cell viability 유지를 위한 세포성장과 에탄을 생성을 완전히 분리시킨 2 bioreactor system의 연구 및 일산화탄소로부터 높은 농도의 에탄올을 생성하는 독창적인 새로운 균주가 분리되어 현재 실험 진행 중이다.

• Journal of Pharmaceutical Investigation
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• 제41권5호
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• pp.309-315
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• 2011

A sensitive and specific liquid chromatographic method coupled with tandem mass spectrometry (LC-MS/MS) was developed for the analysis of ambroxol (active moiety of acebrophylline). After acetonitrile precipitation of proteins from plasma samples, ambroxol and the domperidone (internal standard, IS) were eluted on a C18 column. The isocratic mobile phase was consisted of 10 mM ammonium acetate and methanol (10 : 90, v/v), with flow rate at 0.2 mL/min. A tandem mass spectrometer, as detector, was used for quantitative analysis in positive mode by a multiple reaction monitoring mode to monitor the m/z 379.2${\rightarrow}$264.0 and the m/z 426.2${\rightarrow}$175.1 transitions for ambroxol and the IS, respectively. Twenty four healthy Korean male subjects received two capsules (100 mg ${\times}$ 2) of either the test or the reference formulation of acebrophylline HCl in a 2 ${\times}$ 2 crossover study, this was followed by a 1week washout period between either formulation. $AUC_{0-t}$ (the area under the plasma concentration-time curve) was calculated by the linear trapezoidal rule. $C_{max}$ (maximum plasma drug concentration) and $T_{max}$ (time to reach $C_{max}$) were compiled from the plasma concentration-time data. The 90% confidence intervals for the log transformed data were acceptable range of log 0.8 to log 1.25 (e.g., log 0.8964 - log 0.9910 for $AUC_{0-t}$ log 0.8690 - log 1.0750 for $C_{max}$). The major parameters, $AUC_{0-t}$ and $C_{max}$ met the criteria of Korea Food and Drug Administration for bioequivalence indicating that Acephyll$^{(R)}$ capsule (test) is bioequivalent to Surfolase$^{(R)}$ capsule (reference).

• Biomolecules & Therapeutics
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• 제13권2호
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• pp.118-122
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• 2005

The objective of the present investigation was to study pharmacokinetics of promethazine in Korean healthy subjects using a validated HPLC method. The HPLC analysis was performed on a Capcell Pak CN column with a mixture of acetonitrile-0.02M potassium dihydrogen phosphate (42:58, v/v, pH 6.0) and the analyte was quantified with UV detection at 251 nm. The calibration curve of the drug was linear over the range of 1-40ng/mL in human serum and the limit of quantification (LOQ) was 1 ng/mL. This analytical method was validated and shown to be specific, accurate, precise and reproducible. This method was applied to pharmacokinetic study of promethazine in Korean healthy volunteers following an oral administration of two 25 mg Himazin tablets (50 mg promethazine ${\cdot}$HCI) after overnight fasting. Serum samples were collected at given intervals over a 36-hour period (12 points) and pharmacokinetic parameters were determined from serum concentration-time profile using WinNonlin program. The estimated $AUC_{0__\infty}$, $AUC_{0_\infty}$, $C_{max}$, $T_{max}$ and $t_{1/2}$ of promethazine obtained from Korean healthy subjects were 103.84 ${\pm}$84.30 ng${\cdot}$hr/mL, 87.94${\pm}$81.02 ng${\cdot}$hr/mL, 13.43${\pm}$10.92 ng/mL, 2.00${\pm}$1.16 hr and 5.88${\pm}$3.47 hr, respectively.

• 한국임상약학회지
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• 제22권3호
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• pp.228-233
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• 2012

Purpose: The purpose of this study was to elucidate the effect of dissolved oxygen in alcohol to blood pressure of healthy persons. Methods: Subjects (n=30) were randomized in a double blind crossover study to receive 120 mL, 240 mL, 360 mL of alcohol (Korean spirit, 19.59 v/v%, dissolved oxygen is 8 ppm and 20 ppm). Blood alcohol concentration (BAC) and blood pressure were measured applying Lion SD-400 Alcolmeter$^{(R)}$ Breathalyser and Tensoval duo control. Pharmacokinetic parameters ($C_{max}$, $T_{max}$, $AUC_{last}$, $K_{el}$, $V_d$, Clearance) were calculated using Winnonlin$^{(R)}$ program. The difference of parameters and values were analysed by student t-test using Microsoft$^{(R)}$ Excel program. Results: The $AUC_{last}$ values of 8 ppm group and 20 ppm group in 240 ml administration were $6.15{\pm}2.60cg{\cdot}min/ml$, $5.33{\pm}1.84cg{\cdot}min/ml$ (p<0.05) and those in 360 mL were $11.93{\pm}5.70cg{\cdot}min/ml$, $10.33{\pm}4.60cg{\cdot}min/ml$ (p < 0.01), respectively. Thus, the $AUC_{last}$ was significantly decreased. On the other hands, there was a significant change in systolic blood pressure (SBP) after alcohol administration. All measured value after 360 mL of alcohol administration was significantly decreased (p < 0.01). Conclusions: The dissolved oxygen in alcoholic beverage has no effect on blood pressures but the alcohol administration has an effect on blood pressure. Thus, SBP can be used as a biomarker of alcohol administration and utilized in PK/PD modeling of alcohol.

• 식물조직배양학회지
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• 제21권6호
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• pp.363-367
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• 1994

식물 세포의 신호전달 기작에 있어 calmodulin (CaM)의 역할을 조사하기 위하여 외부기원의 CaM을 식물 세포 내로 주입하였다. 이를 위하여 bovine testis로부터 CaM을 분리, 정제하여 SDS-PAGE상에서 순수함을 확인하였고, 이를 세포 내로 주입한 후 실제 주입 여부를 확인하기 위해 정제된 CaM을 미리 fluorescein isothiocyanate (FITC)로 표식하여 사용하였다. 또한, FITC-CaM complex의 농도에 따른 fluorescent intensity를 측정하여 주입된 CaM의 농도를 결정하였다. 대두 현탁 배양 세포를 saponin (0.1 mg/mL)이 포함된 배지에서 15분간 배양하여 permeabilization시키고,FITC-CaM (1mg/mL)을 30분간 처리한 후 형광현미경으로 조사했을 때 세포질에서 강한 형광이 나타났으며, 이 결과로 외부의 calmodulin이 세포 내로 주입되었음을 확인할 수 있었다. 대두 현탁 배양 세포에 3가지의 세포벽 분해 효소를 처리하여 원형질체를 분리하였고, 이 원형질체를 FITC-CaM이 들어있는 완충용액에 넣고 electroporation 하였을때 capacitance와 field strength가 증가할수록 원형질체의 생존률은 감소하였으나, 세포 내의 fluorescent intensity는 증가하였다. 이것은 외부의 calmodulin이 electroporation에 의해 대두의 원형질체 내로 도입되었음을 의미하는 것이다.

• 한국수산과학회지
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• 제50권4호
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• pp.437-446
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• 2017

To evaluate the consequences of possible fisheries regulations of anchovy Engraulis japonicus in the Korea Strait, we developed and applied a simulation-based yield-per-recruit (Y/R) model that considered temperature-dependent growth and size-dependent mortality, covering the egg to adult stages. We projected changes in commercial yield and egg production of anchovy with respect to varying biological reference points of 1) the instantaneous fishing mortality, 2) the minimum fork length of anchovy allowed to catch for protecting smaller anchovy ($L_{c,min}$), and 3) the maximum fork length allowed to catch for protecting bigger anchovy ($L_{c,max}$). Our Y/R model showed that the anchovy yield will be maximized at ca. $1.4{\times}10^6tons$ when $L_{c,min}$ ranges between 42-60 mm or at ca. $0.8{\times}10^6tons$ when $L_{c,max}$ ranges from 88-160 mm. At $L_{c,min}=30mm$, the present minimum length of catch, our simulations indicated that the anchovy yield can reach a maximum of $1.2{\times}10^6tons$ in the long-term when the present fishing effort, which annually yields ca. $0.2{\times}10^6tons$ of anchovy, can be increased by a factor of 28. We expect that our simulation-based Y/R model can be applied to other commercially-important small pelagic species in which the traditional Beverton-Holt Y/R model is difficult to apply.

• Archives of Pharmacal Research
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• 제27권6호
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• pp.676-681
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• 2004

Acetyl-L-camitine (ALC), a naturally occurring endogenous compound, has been shown to improve the cognitive performance of patients with senile dementia Alzheimer＇s type, and to be involved in cholinergic neurotransmission. Because ALC is an endogenous compound, valida-tion of the analytical methods of ALC in the biological fluids is very important and difficult. This study was presented validation and correction for plasma ALC concentrations and pharmacok-inetics after oral administration of ALC to human volunteers. ALC concentrations in human plasma were corrected by subtracting the concentration of blank plasma from each sample. Precision and accuracy (bias %) for uncorrected ALC concentrations were below 2.6 and 6.5% for intra-days, and 4.0 and 9.4% for inter-days, respectively. Precision and accuracy (bias %)for corrected ALC concentrations were below 10.9 and 6.0% for intra-days, and 10.5 and 16.9% for inter-days, respectively. Quantitation limit was $0.1{\;}\mu\textrm{g}／mL$. After oral administration of a 500 mg ALC tablet to 8 healthy volunteers, the principle pharmacokinetic parameters were 4.2 h of the half-life$ (t_{1/2},{\beta})$, the area under the curve $(AUC_{0{\rightarrow}8){\;}of{\;}9.88{\;}\mu\textrm{g}{\cdot}h/mL$, and 3.1 h of the time ($T_{max}$) to reach $C_{max}$. This study first describes the pharmacokinetic study after oral admin-istration of a single dose of ALC in human volunteers.

• Archives of Pharmacal Research
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• 제28권4호
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• pp.463-468
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• 2005

The purpose of the present study was to develop a standard protocol for imidapril hydrochloride bioequivalence testing. For this reason, a specific LC-MS method was developed and validated for the determination of imidapril in human plasma. A solid-phase extraction cartridge, $Sep-pak^{R}$ C18, was used to extract imidapril and ramipril (an internal standard) from deproteinized plasma. The compounds were separated using a XTerra $MS^{R}$?C18 column ($3.5 {\mu}m, 2.1\times150 mm$) and $acetonitrile-0.1\%$ formic acid (67:33, v/v) adjusted to pH 2.4 by 2 mmol/L ammonium formic acid, as mobile phase at 0.3 mL/min. Imidapril was detected as m/z 406 at a retention time of ca. 2.3 min, and ramipril as m/z 417 at ca. 3.6 min. The described method showed acceptable specificity, linearity from 0.5 to 100 ng/mL, precision (expressed as a relative standard deviation of less than $15\%$), accuracy, and stability. The plasma concentration-versus-time curves of eight healthy male volunteers administered a single dose of imidapril (10 mg), gave an $AUC_{12hr}$ of imidapril of $121.48\pm35.81 ng mL^{-1} h$, and $C_{max} and T_{max}$ values of $32.59\pm9.76 ng/mL and 1.75\pm0.27 h$. The developed method should be useful for the determination of imidapril in plasma with sufficient sensitivity and specificity in bioequivalence study.