1-chloro-11H-pyrido[2,1-b]quinazolin-11-one | 1609121-12-1
中文名称
——
中文别名
——
英文名称
1-chloro-11H-pyrido[2,1-b]quinazolin-11-one
英文别名
1-Chloropyrido[2,1-b]quinazolin-11-one
![1-chloro-11H-pyrido[2,1-b]quinazolin-11-one化学式](data:image/svg+xml;base64,<?xml version="1.0" encoding="UTF-8"?>
<svg xmlns="http://www.w3.org/2000/svg" xmlns:xlink="http://www.w3.org/1999/xlink" width="300" height="300" viewBox="0 0 300 300">
<defs>
<g>
<g id="glyph-0-0">
<path d="M 1.125 4 L 1.125 -15.96875 L 12.453125 -15.96875 L 12.453125 4 Z M 2.40625 2.734375 L 11.1875 2.734375 L 11.1875 -14.6875 L 2.40625 -14.6875 Z M 2.40625 2.734375 "/>
</g>
<g id="glyph-0-1">
<path d="M 2.21875 -16.5 L 5.234375 -16.5 L 12.546875 -2.703125 L 12.546875 -16.5 L 14.71875 -16.5 L 14.71875 0 L 11.703125 0 L 4.390625 -13.8125 L 4.390625 0 L 2.21875 0 Z M 2.21875 -16.5 "/>
</g>
<g id="glyph-0-2">
<path d="M 8.921875 -14.984375 C 7.296875 -14.984375 6.003906 -14.378906 5.046875 -13.171875 C 4.097656 -11.960938 3.625 -10.316406 3.625 -8.234375 C 3.625 -6.160156 4.097656 -4.519531 5.046875 -3.3125 C 6.003906 -2.101562 7.296875 -1.5 8.921875 -1.5 C 10.546875 -1.5 11.828125 -2.101562 12.765625 -3.3125 C 13.710938 -4.519531 14.1875 -6.160156 14.1875 -8.234375 C 14.1875 -10.316406 13.710938 -11.960938 12.765625 -13.171875 C 11.828125 -14.378906 10.546875 -14.984375 8.921875 -14.984375 Z M 8.921875 -16.796875 C 11.234375 -16.796875 13.082031 -16.019531 14.46875 -14.46875 C 15.851562 -12.925781 16.546875 -10.847656 16.546875 -8.234375 C 16.546875 -5.628906 15.851562 -3.550781 14.46875 -2 C 13.082031 -0.445312 11.234375 0.328125 8.921875 0.328125 C 6.597656 0.328125 4.738281 -0.445312 3.34375 -2 C 1.957031 -3.550781 1.265625 -5.628906 1.265625 -8.234375 C 1.265625 -10.847656 1.957031 -12.925781 3.34375 -14.46875 C 4.738281 -16.019531 6.597656 -16.796875 8.921875 -16.796875 Z M 8.921875 -16.796875 "/>
</g>
<g id="glyph-0-3">
<path d="M 14.578125 -15.234375 L 14.578125 -12.875 C 13.828125 -13.570312 13.023438 -14.09375 12.171875 -14.4375 C 11.328125 -14.789062 10.425781 -14.96875 9.46875 -14.96875 C 7.582031 -14.96875 6.132812 -14.390625 5.125 -13.234375 C 4.125 -12.085938 3.625 -10.421875 3.625 -8.234375 C 3.625 -6.054688 4.125 -4.390625 5.125 -3.234375 C 6.132812 -2.085938 7.582031 -1.515625 9.46875 -1.515625 C 10.425781 -1.515625 11.328125 -1.6875 12.171875 -2.03125 C 13.023438 -2.375 13.828125 -2.898438 14.578125 -3.609375 L 14.578125 -1.265625 C 13.796875 -0.734375 12.96875 -0.332031 12.09375 -0.0625 C 11.226562 0.195312 10.304688 0.328125 9.328125 0.328125 C 6.828125 0.328125 4.859375 -0.4375 3.421875 -1.96875 C 1.984375 -3.5 1.265625 -5.585938 1.265625 -8.234375 C 1.265625 -10.890625 1.984375 -12.976562 3.421875 -14.5 C 4.859375 -16.03125 6.828125 -16.796875 9.328125 -16.796875 C 10.316406 -16.796875 11.25 -16.664062 12.125 -16.40625 C 13 -16.144531 13.816406 -15.753906 14.578125 -15.234375 Z M 14.578125 -15.234375 "/>
</g>
<g id="glyph-0-4">
<path d="M 2.140625 -17.203125 L 4.171875 -17.203125 L 4.171875 0 L 2.140625 0 Z M 2.140625 -17.203125 "/>
</g>
</g>
</defs>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.472088 1.495393 L 2.5883 2.003136 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.463736 1.509819 L 3.463736 0.489639 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.463736 1.500224 L 4.329923 1.998373 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.630361 1.403797 L 4.329992 1.80614 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.604935 2.003205 L 1.987374 1.647177 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.513271 1.950332 L 2.513271 2.738314 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.679964 1.950539 L 2.679964 2.738314 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.472088 0.504134 L 2.851559 0.146795 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.463736 0.499302 L 4.338206 -0.004783 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 3.630361 0.595591 L 4.338275 0.187519 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 4.321571 2.003205 L 5.205359 1.495393 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 4.329923 1.988779 L 4.329923 2.734794 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 1.732398 1.24442 L 1.732398 0.489708 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 1.477422 1.646832 L 0.857928 2.003205 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.341745 0.147278 L 1.732398 0.499302 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 2.425126 0.291539 L 1.899092 0.595522 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 4.321571 -0.004783 L 5.205359 0.504134 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 5.197007 1.509819 L 5.197007 0.489639 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 5.030382 1.413392 L 5.030382 0.585997 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 1.74075 0.504134 L 0.857859 -0.004783 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 0.874494 2.003205 L -0.00832774 1.495393 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 0.874494 1.810903 L 0.158297 1.398966 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 0.874494 -0.004783 L -0.00832774 0.504134 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 0.874494 0.187588 L 0.158297 0.600423 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<path fill="none" stroke-width="0.0333333" stroke-linecap="butt" stroke-linejoin="miter" stroke="rgb(0%, 0%, 0%)" stroke-opacity="1" stroke-miterlimit="10" d="M 0.0000242102 1.509819 L 0.0000242102 0.489708 " transform="matrix(56.592331, 0, 0, 56.592331, 2.943942, 64.868337)"/>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-0-1" x="92.519531" y="158.015625"/>
</g>
<g fill="rgb(100%, 5.1%, 5.1%)" fill-opacity="1">
<use xlink:href="#glyph-0-2" x="140.980469" y="242.863281"/>
</g>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-0-1" x="141.425781" y="73.117188"/>
</g>
<g fill="rgb(9.977717%, 78.158784%, 9.977717%)" fill-opacity="1">
<use xlink:href="#glyph-0-3" x="237.359375" y="243.0625"/>
<use xlink:href="#glyph-0-4" x="253.165438" y="243.0625"/>
</g>
</svg>
)
CAS
1609121-12-1
化学式
C12H7ClN2O
mdl
——
分子量
230.653
InChiKey
JYJMZKLQEGHYNF-UHFFFAOYSA-N
BEILSTEIN
——
EINECS
——
-
物化性质
-
计算性质
-
ADMET
-
安全信息
-
SDS
-
制备方法与用途
-
上下游信息
-
文献信息
-
表征谱图
-
同类化合物
-
相关功能分类
-
相关结构分类
计算性质
-
辛醇/水分配系数(LogP):2.2
-
重原子数:16
-
可旋转键数:0
-
环数:3.0
-
sp3杂化的碳原子比例:0.0
-
拓扑面积:32.7
-
氢给体数:0
-
氢受体数:2
反应信息
-
作为产物:描述:4-chloro-N-(pyridin-2-yl)indole 在 1-benzyl-1H-benzo[d]imidazole 、 氧气 、 copper diacetate 、 三甲基乙酸 作用下, 以 二甲基亚砜 为溶剂, 反应 48.0h, 以48%的产率得到1-chloro-11H-pyrido[2,1-b]quinazolin-11-one参考文献:名称:N-吡啶基吲哚的铜催化有氧氧化导致稠合喹唑啉酮摘要:我们开发了 N-吡啶基吲哚的绿色和有氧氧化。这种方法可以通过铜 (II)/空气系统执行以提供所需的喹唑啉酮。一系列取代的 N-吡啶基吲哚是提供这种转化的合适底物。从机理上讲,N-吡啶基吲哚的有氧氧化过程涉及单电子转移氧化、分子氧的捕获和一氧化碳的排出。DOI:10.1002/ejoc.202100618
文献信息
-
Condensation of anthranilic acids with pyridines to furnish pyridoquinazolones via pyridine dearomatization作者:Yajun Yang、Cuiju Zhu、Min Zhang、Shijun Huang、Jingjing Lin、Xiandao Pan、Weiping SuDOI:10.1039/c6cc07365d日期:——The unprecedented carbodiimide-mediated condensation between pyridines and anthranilic acids via pyridines dearomatization at room temperature has been developed to provide a straightforward approach to pyridoquinazolones. The value of this approach...
-
Palladium‐Catalyzed Carbonylative Cyclization of Arenes by CH Bond Activation with DMF as the Carbonyl Source作者:Jianbin Chen、Jian‐Bo Feng、Kishore Natte、Xiao‐Feng WuDOI:10.1002/chem.201503314日期:2015.11.9autoclave‐free protocol for the synthesis of 11H‐pyrido[2,1‐b]quinazolin‐11‐ones has been developed. Quinazolinones, which are omnipresent motif in many pharmaceuticals and agrochemicals, were prepared in good yields by CH bond activation and annulation using DMF as the CO surrogate. A 13CO‐labelled DMF control experiment demonstrated that CO gas was released from the carbonyl of DMF with acid as
-
Ultrasound assisted Cu-catalyzed Ullmann-Goldberg type coupling-cyclization in a single pot: Synthesis and in silico evaluation of 11H-pyrido[2,1-b]quinazolin-11-ones against SARS-CoV-2 RdRp作者:Matta Manikanttha、Kolli Deepti、Mandava Bhuvan Tej、Mandava Bhagya Tej、A. Gopi Reddy、Ravikumar Kapavarapu、Deepak Kumar Barange、M. V Basaveswara Rao、Manojit PalDOI:10.1016/j.molstruc.2023.135044日期:2023.5The in silico evaluation of 11H-pyrido[2,1-b]quinazolin-11-one derivatives against SARS-CoV-2 RdRp was undertaken based on the reports on antiviral activities of this class of compounds in addition to the promising interactions of the antiviral drug penciclovir as well as quinazoline derivatives with SARS-CoV-2 RdRp in silico. The target compounds were prepared via an Ullmann–Goldberg type coupling11 H- pyrido[2,1- b ]quinazolin-11-one 衍生物抗 SARS-CoV-2 RdRp 的计算机评价是根据此类化合物的抗病毒活性报告以及抗病毒药物喷昔洛韦以及喹唑啉衍生物与 SARS-CoV-2 RdRp in silico。目标化合物通过Ullmann-Goldberg 型偶联,随后在单个罐中进行环化(涉及酰胺化)。该方法涉及 2-碘苯甲酸酯与 2-氨基吡啶或喹啉-2-胺或噻唑-2-胺在超声下的 CuI 催化反应,以可接受的 (51–93%) 收率生成预期产物。在计算机上评估了合成的 11 H-吡啶并[2,1 - b ]喹唑啉-11-酮衍生物与 SARS-CoV-2 RdRp (PDB: 7AAP)的分子相互作用。该研究表明,尽管这些化合物中没有一种显示出比喷昔洛韦更好的相互作用,但化合物3a和3n似乎与3b具有可比性似乎几乎可以与 favipiravir
-
Palladium-Catalyzed C(sp<sup>2</sup>)–H Pyridocarbonylation of <i>N</i>-Aryl-2-aminopyridines: Dual Function of the Pyridyl Moiety作者:Dongdong Liang、Yimiao He、Qiang ZhuDOI:10.1021/ol501070g日期:2014.5.16An efficient synthesis of 11H-pyrido[2,1-b]-quinazolin-11-one through palladium-catalyzed C(sp(2))-H pyridocarbonylation of N-aryl-2-aminopyridines has been developed. The pyridyl group acts as an intramolecular nucleophile for the first time in C-H carbonylation reactions.
-
Pd/C-catalyzed carbonylative C–H activation with DMF as the CO source作者:Jianbin Chen、Kishore Natte、Xiao-Feng WuDOI:10.1016/j.tetlet.2015.09.142日期:2015.11An interesting Pd/C-catalyzed carbonylative cyclization of N-arylpyridin-2-amine derivatives via C-H activation has been developed. With DMF as the CO source, the desired quinazolinones were formed in moderate to good yields with good functional group tolerance. (C) 2015 Elsevier Ltd. All rights reserved.
同类化合物
(12羟基吲[2,1-b〕喹唑啉-6(12H)-酮)
黑暗猝灭剂BHQ-3,BHQ-3NHS
鸭嘴花酚碱
鸭嘴花碱酮;(S)-2,3-二氢-3,7-二羟基吡咯并[2,1-b]喹唑啉-9(1H)-酮
鸭嘴花碱酮
鸭嘴花碱盐酸盐
鲁米诺单钠盐
鲁米诺
骆驼蓬碱
颜料蓝64
颜料蓝60
顺式-卤夫酮
顺式-(喹喔啉-2-基)丙烯腈1,4-二氧化物
非奈利酮
青黛酮
雷替曲塞杂质1
阿法替尼杂质J
阿法替尼杂质I
阿法替尼杂质28
阿法替尼杂质18
阿法替尼杂质13
阿法替尼杂质
阿法替尼中间体
阿法替尼
阿法替尼
阿朴藏红
阿巴康唑
阿夫唑嗪杂质A
阿夫唑嗪杂质
阿夫唑嗪EP杂质C
阿夫唑嗪
阿喹司特
阿呋唑嗪杂质
阿呋唑嗪杂质
铜迈星
铁诱导细胞死亡激活剂
钠四丙基硼酸酯
酸性蓝98
酸性红101
酮色林醇
酞联氮基[2,3-b]酞嗪-5,14-二酮,7,12-二氢-
酞嗪-5-羧酸
酞嗪-2-氧化物
酚藏花红
酚嗪
酒石酸溴莫尼定
邻苯二甲酰肼
还原黄6GD
还原蓝6
达尼喹酮
联系我们
关注我们
公众号
