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임상연구 : 개흉술 후 통증 조절을 위한 지속적 척추주위 차단시 Bupivacaine의 농도 비교
진희철 ( Hee Cheol Jin ),최상구 ( Sang Gu Choi ),김상현 ( Sang Hyun Kim ),채원석 ( Won Seok Choi ),이정석 ( Jeong Seok Lee ),김용익 ( Yong Ik Kim ) 대한마취과학회 2007 Korean Journal of Anesthesiology Vol.53 No.2
Background: There are many reports showing that a thoracic paravertebral block (TPB) can be used for post-thoracotomy pain control. However, the proper concentration of local anesthetics for TPB has not been established. The aim of this study was to define the proper concentration of bupivacaine for TPB after a thoracotomy. Methods: Sixty patients were allocated randomly into one of the following three groups: thoracic paravertebral 0.5%, 0.25%, or 0.125% bupivacaine at a rate of 0.1 ml/kg/h (kg: ideal body weight). The resting and coughing visual analogue scale (VAS) score, cumulative dose of fentanyl, and the 5 point satisfaction scale were checked. Results: 0.5% and 0.25% bupivacaine showed lower VAS score and cumulative dose of fentanyl than 0.125%. There was no difference in the satisfaction scale between the 3 groups. There was no difference between the 0.5% and 0.25% bupivacaine in all parameters measured. Conclusions: 0.25% bupivacaine used for TPB is more effective when used for pain control after a thoracotomy than 0.5% and 0.125% bupivacaine. (Korean J Anesthesiol 2007; 53: 212~6)
A Study on the Hydrated and Dehydrated $Mn^{2+}$-Exchanged Zeolite A
박종열,김양,김은식,최상구,Jong Yul Park,Yang Kim,Un Sik Kim,Sang Gu Choi Korean Chemical Society 1989 대한화학회지 Vol.33 No.6
$Mn^{2+}$-치환 제올라이트 A는 가열 탈수되어도 그 구조가 열적을 안정하였다. $Mn_{4,5}Na_3-A$의 수화상태 및 탈수상태에 있어서의 골조원자, 이온 및 물분자들의 위치와 결합에너지를 몇가지 퍼텐셜 함수들을 써서 계산하여 구하였다. 탈수상태의 $Mn_{4,5}Na_3-A$에 있어서 골조원자들의 결합에너지는 열적으로 안정한 것으로 알려져 있는 탈수상태의 $Ca^{2+}$-치환 제올라이트 A($Ca_6$-A) 및 $Co^{2+}$- 치환제올라이트 A($Co_4Na_4-A$)의 그것과 비슷하였다. $Mn^{2+}$-치환 제올라이트 A 골조 내에는 결합에너지의 결합형식이 서로 다른 세 가지 그룹의 물분자들 즉 인접 물분자 또는 골조 산소원자와 수소결합을 하고 있는 물; W(I), $Na^+$이온에 배위되면서 인접 물 분자와 수소결합을 하는 물; W(II) 및 $Mn^{2+}$에 배위면서 수소결합을 하는 W(III)그룹의 물분자들이 존재하였으며 그들의 결합에너지 및 탈수반응의 활성화에너지의 크기 순서는 W(III) > W(II) > W(I)이였다. The positions and interaction energies of framework atoms and water molecules of $Mn^{2+}$-exchanged zeolite A were calculated using some potential energy functions and an optimization program. The sum of interaction energies of framework atoms in dehydrated $Mn_{4,5}Na_3-A$ was approximately the same as those of thermally stable $Ca^{2+}$-or $Mg^{2+}$-exchanged zeolite A. Since $Mn^{2+}$ ions can form good coordination bonds with framework oxygens even in dehydrated state, $Mn^{2+}$-exchanged zeolite A is considered to be thermally stable. The optimized positions of framework atoms and ions in this work are agreed well with the crystallographic data. Three groups of water molecules are found in hydrated $Mn^{2+}$-exchanged zeolite A; W(I) group of water molecules having only hydrogen bonds, W(II) group coordinated to $Na^+$ ion, and W(III) group coordinated to $Mn^{2+}$ ion. The average binding energy of each group of water molecules decrease in the order of W(III) > W(II) > W(I). The activation energies in the dehydration reaction of each group of water molecules increased in accordance with their binding energy.
박종렬,김양,김은식,최상구,Jong Yul Park,Yang Kim,Un Sik Kim,Sang Gu Choi 대한화학회 1989 대한화학회지 Vol.33 No.4
제올라이트 A($Na_{12}Al_{12}Si_{12}O_{48}$ ; $Na_{12}-A$)를 $Mg^{2+}$, $Ca^{2+}$, $Zn^{2+}$ 및 $Co^{2+}$ 등의 2가 이온으로 치환하여 얻어진 $Mg_4Na_4Al_{12}Si_{12}O_{48}$($Mg_4Na_4-A$), $Ca_6Al_{12}Si_{12}O_{48}$($Ca_6-A$), $Zn_5Na_2Al_{12}Si_{12}O_{48}$($Zn_5Na_2-A$) 및 $Co_4Na_4Al_{12}Si_{12}O_{48}$($Co_4Na_4-A$)의 수화구조와 탈수구조에 있어서 골조원자, 양이온 및 물분자들의 위치와 에너지를 몇가지 퍼텐셜 함수를 써서 계산하여 구하였다. 탈수가 될 때 양이온은 수화구조에서의 6-ring이나 8-ring의 골조산소 쪽으로 이동하였으며 일반적으로 2가 이온치환 제올라이트 A가 완전탈수될 때는 그 골조가 제올라이트 A의 골조보다 불안정하였다. 수화상태의 경우 골조내에는 인접물분자 또는 골조산소원자와 수소결합하는 물; W(III), $Na^+$ 이온에 배위된 물; W(II) 및 2가 이온에 배위되는 물; W(I) 등이 존재하였으며 이들 세 그룹의 물분자들의 탈수에 대응하는 세개의 DTA 흡열피크를 관측하였다. The positional parameters of framework atoms, cations, and water molecules in hydrated and dehydrated $Mg_4Na_4-A$, $Ca_6-A$, $Zn_5Na_2-A$ and $Co_4Na_4-A$ were determined by the optimization technique using some potential energy functions and VAIOA optimization program. Upon dehydration, cations in hydrated states move toward the framework oxygens of 6 rings. Frameworks of fully dehydrated zeolite A are more stable than those of fully dehydrated divalent cation exchanged Zeolite A. There are three different kinds of water molecules in divalent cation exchanged Zeolite A; W(III) (water molecules having hydrogen bonds), W(II) (water molecules associated with $Na^+$ ions), and W(I) (water molecules associated with divalent cations). Three different DTA endothermic peaks were observed corresponding to the dehydration of three different kinds of water molecules in divalent cation exchanged Zeolite A.