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이우영,Woo Young Lee Korean Chemical Society 1974 대한화학회지 Vol.18 No.1
A practical method applicable to the synthesis of aromatic dihydrazines was proposed by reducing tetrazonium salt in strong mineral acid media. By diazotizing p-phenylenediamine with sodium nitrite in a medium of concentrated hydrochloric acid or 45 % perchloric acid at $-5 {\sim} -10{\circ}C$ and reducing the tetrazonium salt with stannous chloride, p-phenylenedihydrazine (PPDH) was separated in the form of hydrochloride as colorless fine needles. Since PPDH was subject to oxidation and unstable, the free base could not be isolated. PPDH${\cdot}$2HCl was decomposed at $^180{\circ}C$ without showing sharp melting point. It behaved largely as aromatic monohydrazines, and reacted immediately with aldehydes and ketones in acetate buffer, giving generally yellow to brownish condensation products, dihydrazones. This suggests that PPDH will react with dicarbonyl compounds producing high molecular polymers or cyclization products. 芳香族디아민을 강한 광물산의 妓質中에서 디아조化하고, 이때 얻은 테트라아조늄염을 還元함으로서 芳香族 디히드라진類의 合成에 응용할 수 있는 실용적인 方法을 創案하였다. 파라페닐렌디아민을 진한 鹽酸 또는 45% 過鹽素酸을 妓質로 해서 低溫에서 아질산나트륨으로디아조化하여 얻은 테트라아조늄鹽을 염화주석(II)으로 還元하여 파라페닐렌디히드라진(PPDH)을 鹽酸鹽의 微細한 針狀結晶으로 分離하였다. PPDH의 遊離鹽期는 空氣中에서 酸化되기 쉽기 때문에不安定하여 分離할수 없었다. PPDH${\cdot}$2HCl은 明確한 융점을 보이지 않고 $^180{\circ}C$에서 炭化되면서 分解하였다. PPDH는 芳香族 모노히드라진과 유사한 性質이 있었으며, 초산염의 緩衝溶液에서 알데히드 및 케톤과 반응시키면 재빨리 反應하여 노랑색 내지 갈색을 띤 縮合化合物인 디히드라존이 生成되었다. 이것은 PPDH가 디카르보닐化合物과 反應하여 高分子의 폴리마나 還狀縮合物을 形成할 것임을 暗示한다.
이우영,Lee Woo Young Korean Chemical Society 1978 대한화학회지 Vol.22 No.5
Tetrazonium 염을 거쳐서 m-phenylenedihydrazine (MPDH)을 합성할 수 있었다. 즉, m-phenylenediamine을 진한 염산의 매질 속에서 $-10∼-5^{\circ}C$로 유지하고아질산나트륨으로 테트라 아조화한 다음, 이때 생긴 tetrazonium 염을 염화주석(II)으로 환원시켜 MPDH를 염산염의 꼴로 얻어 알코올에서 재결정 할 수 있었다. MPDH의 유리염기는 불안정하기 때문에 공기 중에서는 안정한 상태로 얻기 어려우며, 그 염산염은 명확한 녹는 점을 가지지 않고 $185^{\circ}C$에서 분해하였다. MPDH도 방향족 monohydrazine의 경우 처럼 mono 또는 dicarbnyl 화합물과 쉽게 축합반응을 일으켜서 dihydrazone 또는 고리모양 화합물을 생성하였다. MPDH와 carbonyl 화합물과의 반응에서 얻은 여러가지 화합물의 구조를 결정하였다. m-Phenylenedihydrazine(MPDH) was prepared via tetrazonium salt: m-Phenylenediamine was tetrazotized with sodium nitrite at $-10∼-5^{\circ}C$ in concentrated hydrochloric acid medium, reused tetrazonium salt was reduced with stannous chloride and MPDH was separated as dihydrochloride which was recrystallized from alcohol. The free base of MPDH being unstable it could hardly be obtained in the air. $MPDH{\cdot}2HCl$ did not show sharp melting point but decomposed at $185^{\circ}C$. MPDH, like aromatic monohydrazines, condensed with mono-and dicarbonyl compounds giving dihydrazones or cyclic compounds. The structures of condensation products obtained from the reaction of MPDH with carbonyl compounds are determined.
이우영,김세훈,장석종,Lee, Woo-Young,Kim, Se-Hoon,Chang, Seok-Jong 대한생리학회 1990 대한생리학회지 Vol.24 No.1
The contractile mechanisms of serotonin were investigated in the renal artery of a rabbit. The helical strips of isolated renal artery were immersed in the normal or $Ca^{2+}$-free tris-buffered Tyrode's solution, which was equilibrated with 100% $O_{2}$ at $35^{\circ}C$. The contraction by serotonin or norepinephrine (NE) began at $1{\times}10^{-7}\;M$ and reached the maximal contraction at $1{\times}10^{-5}\;M$. The maximal contraction by serotonin corresponded to $58.1{\pm}4.2%$ of maximal contraction by NE. Cyproheptadine, a serotonin receptor blocker, shifted the concentration-response curve to the right without any reduction in the maximum response but shifted that of NE to the right with reduction in maximum response. And phentolamine, an ${\alpha}-receptor$ blocker, shifted the concentration-response curve of serotonin or NE without any reduction in maximum responses. The $pA_{2}$ values for cyproheptadine against serotonin and NE were $10.35{\pm}0.04$ and $8.45{\pm}0.13$, respectively. The $pA_{2}$ values for phentolamine against serotonin and NE were $6.87{\pm}0.04$ and $8.14{\pm}0.08$, respectively. after the pretreatment with 6-hydroxydopamine, the contraction induced by 100 mM $K^{+}$, tyramine and serotonin reduced to $83.0{\pm}2.0$, $26.8{\pm}6.2$ and $82.0{\pm}3.5%$ of control, respectively. The contraction by serotonin in the $Ca^{2+}$-free Tyrode's solution was increased and sustained with the addition of $Ca^{2+}$ extracellulary. The serotonin-sensitive intracellular $Ca^{2+}$ pool was depleted completely by the pretreatment with NE, but the NE-sensitive intracellular $Ca^{2+}$ pool was depleted partially by the pretreatment with serotonin. From the above results, it is suggested that the contraction induced by serotonin in the renal artery of a rabbit may be due to mechanisms in which serotonin acts directly on specific serotonin receptors and also acts indirectly on ${\alpha}-adrenoceptors$ by displacing NE from neuronal stores.