Jürgen B Bulitta

Publications (4)8.31 Total impact

• Article: Population pharmacokinetics of a novel histone deacetylase inhibitor, cyclo{(2S)-2-amino-8-[(aminocarbonyl)hydrazono] decanoyl-1-L-tryptophyl-L-isoleucyl-(2R)-2-piperidinecarbonyl} (SD-2007), and its metabolic conversion to apicidin after intravenous injection and oral administration in rats.

  Beom Soo Shin, Jürgen B Bulitta, Deok Ki Hong, Hye Youn Kim, Min Ki Kim, Yohan Choi, Jong Bong Lee, Sang Wook Hwang, Mann Hyung Lee, Sun Dong Yoo
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  ABSTRACT: This study assessed the population pharmacokinetics and metabolic conversion of a novel histone deacetylase (HDAC) inhibitor, SD-2007, into its active metabolite, apicidin, in rats. SD-2007 was given to rats by intravenous injection (4 mg/kg) and oral administration (40 mg/kg). Serum concentrations of SD-2007 and apicidin were determined by LC-MS/MS. All concentrations were analyzed using a population pharmacokinetic model with 9 compartments in S-ADAPT. The area under the curve for apicidin was 96 ± 16 mg·h/ml after 4 mg/kg administered intravenously and 2,455 ± 1,211 mg·h/ml after 40 mg/kg given orally. The population pharmacokinetic model described all profiles well. After oral administration of SD-2007, the median absolute bioavailability of SD-2007 was 6.67% (range 3.83-9.89) and the median apparent bioavailability was 22.3% (range 15.7-35.8) for apicidin, whereas only a median of 8.85% (range 7.57-9.34) of an intravenous SD-2007 dose was converted to apicidin. Oral SD-2007 displayed a substantial presystemic metabolism to active apicidin. The high serum concentrations of apicidin after oral administration of SD-2007 may cause significant HDAC inhibition.
  Chemotherapy 01/2011; 57(3):259-67. · 1.82 Impact Factor
• Article: Prediction of human pharmacokinetics and tissue distribution of apicidin, a potent histone deacetylase inhibitor, by physiologically based pharmacokinetic modeling.

  Beom Soo Shin, Jürgen B Bulitta, Joseph P Balthasar, Minki Kim, Yohan Choi, Sun Dong Yoo
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  ABSTRACT: The objectives of this study were to develop physiologically based models for the pharmacokinetics (PK) and organ distribution of apicidin in rats and mice and to predict human PK in blood and organs. The PK of apicidin was characterized in rats and mice after i.v. bolus injection, and distribution to various tissues was determined in rats following i.v. infusions at steady state. The developed models were prospectively validated within rat and within mouse and by scaling from rat to mouse using data after multiple i.v. injections. Human PK was predicted by the physiologically based modeling using intrinsic clearance data for humans from in vitro experiments. The Cl(s) predicted for human (9.8 ml/min/kg) was lower than those found in mice (116.9 ml/min/kg) and rats (61.6 ml/min/kg), and the V(ss) predicted for human (1.9 l/kg) was less than in mice (2.0 l/kg) and rats (2.5 l/kg). Consequently, the predicted t (1/2) was longer in human (2.3 h) than in mice and rats (0.4 and 0.9 h, respectively). The highest concentrations of apicidin were predicted in liver followed by adipose tissue, kidney, lung, spleen, heart, arterial blood, venous blood, small intestine, stomach, muscle, testis, and brain. The developed models adequately described the PK of apicidin in rats and mice and were applied to predict human PK. These models may be useful in predicting human blood and tissue concentrations of apicidin under different exposure conditions.
  Cancer Chemotherapy and Pharmacology 11/2010; 68(2):465-75. · 2.83 Impact Factor
• Article: Physiologically based pharmacokinetics of zearalenone.

  Beom Soo Shin, Seok Hyun Hong, Jürgen B Bulitta, Jong Bong Lee, Sang Wook Hwang, Hyoung Jun Kim, Seung Du Yang, Hae-Seong Yoon, Do Jung Kim, Byung Mu Lee, Sun Dong Yoo
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  ABSTRACT: The objectives of this study were to (1) develop physiologically based pharmacokinetic (PBPK) models for zearalenone following intravenous (i.v.) and oral (p.o.) dosing in rats and (2) predict concentrations in humans via interspecies scaling. The model for i.v. dosing consisted of vein, artery, lung, liver, spleen, kidneys, heart, testes, brain, muscle, adipose tissue, stomach, and small intestine. To describe the secondary peak phenomenon observed after p.o. administration, the absorption model was constructed to reflect glucuronidation, biliary excretion, enterohepatic recirculation, and fast and slow absorption processes from the lumenal compartment. The developed models adequately described observed concentration-time data in rats after i.v. or p.o. administration. Upon model validation in rats, steady-state zearalenone concentrations in blood and tissues were simulated for rats after once daily p.o. exposures (0.1 mg/kg/d). The average steady-state blood zearalenone concentration predicted in rat was 0.014 ng/ml. Subsequently, a daily human p.o. dose needed to achieve the same steady-state blood concentration found in rats (0.014 ng/ml) was determined to be 0.0312 mg/kg/d or 2.18 mg/70 kg/d. The steady-state zearalenone concentration-time profiles in blood and tissues were also simulated for human after multiple p.o. administrations (dose 0.0312 mg/kg/d). The developed PBPK models adequately described the pharmacokinetics in rats and may be useful in predicting human blood and tissue concentrations for zearalenone under different p,o, exposure conditions.
  Journal of Toxicology and Environmental Health Part A 01/2009; 72(21-22):1395-405. · 1.83 Impact Factor
• Article: Disposition, oral bioavailability, and tissue distribution of zearalenone in rats at various dose levels.

  Beom Soo Shin, Seok Hyun Hong, Jürgen B Bulitta, Sang Wook Hwang, Hyoung Jun Kim, Jong Bong Lee, Seung Du Yang, Ji Eun Kim, Hae-Seong Yoon, Do Jung Kim, Sun Dong Yoo
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  ABSTRACT: This study was conducted to characterize the disposition, oral bioavailability, and tissue distribution of zearalenone in rats. The pharmacokinetics and tissue distribution of zearalenone were studied after intravenous (i.v.) or oral (p.o.) administration at doses ranging from 1 to 8 mg/kg in intact and bile duct-cannulated rats. Serum, bile, and urine concentrations were determined by liquid chromatography and mass spectroscopy (LC/MS/MS) and tissue concentrations by high-performance liquid chromatography (HPLC)/fluorescence detection assays. Noncompartmental methods were used for pharmacokinetic analysis. Average Cl(s) (range 5.0-6.6 L/h/kg) and V(dss) (range 2-4.7 L/kg) remained unaltered over an i.v. dose range from 1 to 8 mg/kg, and area under the concentration-time curve (AUC) and initial peak concentrations increased linearly with dose. Minimal quantities of zearalenone were excreted unchanged in urine (f(e,urine) 0.5 +/- 0.2%) and bile (f(e,bile) 0.91 +/- 0.64%). After p.o. administration of 8 mg/kg, zearalenone was rapidly absorbed and serum concentration-time profiles showed a distinct second peak. The absolute oral bioavailability was low (2.7%). Comparing bile duct-cannulated to intact rats at a dose of 8 mg/kg, the impact of biliary excretion on overall pharmacokinetics was more pronounced after p.o. than after i.v. administration. Upon i.v. infusion to steady state, the highest zearalenone concentration was found in small intestine, followed by kidneys, liver, adipose tissue, and lung. Zearalenone concentrations in stomach, heart, brain, spleen, muscle, and testes were lower than those found in serum. The pharmacokinetics and tissue distribution data from this study may be useful to develop physiologically based pharmacokinetic (PBPK) models for zearalenone and subsequently to predict the pharmacokinetics and toxicity in humans.
  Journal of Toxicology and Environmental Health Part A 01/2009; 72(21-22):1406-11. · 1.83 Impact Factor