2'-phenylspiro[cyclohexane-1,3'-indole]
中文名称
——
中文别名
——
英文名称
2'-phenylspiro[cyclohexane-1,3'-indole]
英文别名
2'-Phenylspiro[cyclohexane-1,3'-indole]
![2'-phenylspiro[cyclohexane-1,3'-indole]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 0.9375 3.3125 L 0.9375 -13.25 L 10.328125 -13.25 L 10.328125 3.3125 Z M 1.984375 2.28125 L 9.28125 2.28125 L 9.28125 -12.1875 L 1.984375 -12.1875 Z M 1.984375 2.28125 "/>
</g>
<g id="glyph-0-1">
<path d="M 1.84375 -13.6875 L 4.34375 -13.6875 L 10.40625 -2.234375 L 10.40625 -13.6875 L 12.203125 -13.6875 L 12.203125 0 L 9.71875 0 L 3.640625 -11.453125 L 3.640625 0 L 1.84375 0 Z M 1.84375 -13.6875 "/>
</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 3.587131 1.807983 L 2.995387 0.993275 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 3.587131 1.807983 L 4.545488 1.49763 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 3.587131 1.807983 L 2.599893 2.017964 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 3.587131 1.807983 L 4.263016 2.559022 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 3.008953 1.000099 L 1.990589 1.000099 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 3.000381 1.000099 L 3.405197 0.442063 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 3.206367 1.000099 L 3.540107 0.539854 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 4.538497 1.49996 L 4.538497 0.499822 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 4.705118 1.40375 L 4.705118 0.596033 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 4.532089 1.496215 L 5.412713 2.005064 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 2.612294 2.006812 L 2.29728 2.977238 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 4.259521 2.542793 L 3.944424 3.512387 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 2.004987 0.991776 L 1.495222 1.874315 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 2.000243 1.000099 L 1.495222 0.125468 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 1.807739 1.000099 L 1.399012 0.292171 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 3.835147 0.271531 L 4.545488 0.502069 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 4.532089 0.503484 L 5.412713 -0.00478251 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 5.395984 2.005064 L 6.279022 1.495133 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 5.396067 1.81256 L 6.112318 1.398923 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 2.293784 2.960925 L 2.975746 3.717208 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 3.956825 3.501234 L 2.959849 3.712131 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 1.509621 1.865992 L 0.490341 1.865992 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 1.41341 1.699372 L 0.586551 1.699372 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 1.509621 0.13379 L 0.490341 0.13379 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 5.395984 -0.00478251 L 6.279022 0.504649 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 5.396067 0.187638 L 6.112318 0.60086 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 6.270699 1.509531 L 6.270699 0.490168 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 0.504739 1.874315 L -0.00477633 0.991776 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 0.504739 0.125468 L -0.00477633 1.008505 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<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 0.601032 0.292171 L 0.187644 1.008422 " transform="matrix(46.93494, 0, 0, 46.93494, 2.903864, 62.954935)"/>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-0-1" x="164.246094" y="78.765625"/>
</g>
</svg>
)
CAS
——
化学式
C19H19N
mdl
——
分子量
261.367
InChiKey
YKOIKEAYFPUWFQ-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):5
-
重原子数:20
-
可旋转键数:1
-
环数:4.0
-
sp3杂化的碳原子比例:0.32
-
拓扑面积:12.4
-
氢给体数:0
-
氢受体数:1
反应信息
-
作为反应物:描述:2'-phenylspiro[cyclohexane-1,3'-indole] 在 sodium cyanoborohydride 、 溶剂黄146 作用下, 以 1,2-二氯乙烷 为溶剂, 生成 2'-phenylspiro(cyclohexane-1,3-indoline)参考文献:名称:甲烷单加氧酶模拟不对称氧化:自组装 μ-羟基、羧酸盐桥联二铁 (III) 催化的对映选择性脱氢摘要:模拟天然存在的金属酶以丰富催化不对称氧化反应的多样性是现代化学的长期目标。为此,已经设计和合成了一系列甲烷单加氧酶 (MMO) 模拟手性羧酸桥联 (μ-羟基) 二铁 (III) 二聚体配合物,使用 salan 作为基础配体和芳基羧酸钠作为添加剂。手性二铁配合物在使用环境友好的过氧化氢作为氧化剂的二氢吲哚的脱氢动力学拆分中表现出高效的催化反应性。特别是复杂的C9带有空间阻碍的salan配体和2-萘甲酸酯桥被确定为手性识别方面的最佳催化剂。进一步的研究表明,这种 MMO 模拟手性催化剂可以很容易地在脱氢条件下通过自组装生成。该自组装催化体系适用于一系列具有多个立构中心和多种取代基模式的二氢吲哚,效率高,手性识别水平高(选择性因子高达153)。进一步检查了生物活性分子的后期脱氢动力学分辨率。DOI:10.1021/jacs.2c00638
-
作为产物:描述:环己基硼酸 在 2-mesityl-6,7-dihydro-5H-pyrrolo[2,1-c][1,2,4]triazol-2-ium tetrafluoroborate 、 potassium phosphate 、 [Ir(dF(H)ppy)2(dtbbpy)](PF6) 、 溶剂黄146 作用下, 以 乙腈 为溶剂, 生成 2'-phenylspiro[cyclohexane-1,3'-indole]参考文献:名称:通过光和 NHC 双催化使用游离烷基硼酸实现能量转移的自由基酰化摘要:交叉偶联反应作为最流行的酮合成方案之一而广受好评。作为重要的偶联伙伴,实验室稳定且市售的烷基硼酸广泛用于过渡金属催化,但很少用作酰化偶联反应的自由基前体。在此,我们报道了通过 NHC/光双催化使用游离烷基硼酸实现能量转移的自由基酰化。该方案可以有效促进烷基硼酸与酰基咪唑之间的铃木型交叉偶联以及烯烃的多组分烷基酰化,从而产生具有结构多样性的各种酮。此外,酮产品可以很容易地转化为大量结构有趣的精细化学品。初步机理研究揭示了独特的自由基反应机理。DOI:10.1021/acscatal.3c06027
文献信息
-
Oxidation of Nonactivated Anilines to Generate <i>N</i>-Aryl Nitrenoids作者:Tianning Deng、Wrickban Mazumdar、Russell L. Ford、Navendu Jana、Ragda Izar、Donald J. Wink、Tom G. DriverDOI:10.1021/jacs.9b13599日期:2020.3.4and selective C-NAr and C-C bond formation to yield spirocyclic- or bicyclic 3H-indoles or benzazepinones. Our experiments demonstrate the breadth of these oxidative processes, uncover underlying fundamental elements that control selectivity and demonstrate how the distinct reactivi-ty patterns embedded in N-aryl nitrenoid reactive intermediates can enable access to functionalized 3H-indoles or benzazepinones已开发出 2-取代苯胺的低温无保护基氧化以生成亲电 N-芳基氮烯中间体,该中间体可以参与 C-NAr 键的形成以构建功能化的 N-杂环。将 2-取代苯胺暴露于 PIFA 和三氟乙酸或 10 mol% 的 Sc(OTf)3 会触发类氮烯类化合物的形成,然后形成生产性和选择性的 C-NAr 和 CC 键,以产生螺环或双环 3H-吲哚或苯并氮杂酮。我们的实验证明了这些氧化过程的广度,揭示了控制选择性的潜在基本要素,并证明了嵌入在 N-芳基氮烯类反应中间体中的独特反应模式如何能够获得功能化的 3H-吲哚或苯并氮杂酮。
-
I(III)-Catalyzed Oxidative Cyclization–Migration Tandem Reactions of Unactivated Anilines作者:Tianning Deng、Emily Shi、Elana Thomas、Tom G. DriverDOI:10.1021/acs.orglett.0c03497日期:2020.11.20An I(III)-catalyzed oxidative cyclization–migration tandem reaction using Selectfluor as the oxidant was developed that converts unactivated anilines into 3H-indoles is reported herein. The reaction requires as little as 1 mol % of the iodocatalyst and is mild, tolerating pyridine and thiophene functional groups, and the dependence of the diastereoselectivity of the process on the identity of the iodoarene本文报道了使用 Selectfluor 作为氧化剂的 I(III) 催化氧化环化-迁移串联反应,将未活化的苯胺转化为 3 H-吲哚。该反应只需要 1 mol% 的碘催化剂,并且是温和的,可耐受吡啶和噻吩官能团,并且该过程的非对映选择性依赖于碘芳烃或碘代烷烃预催化剂的特性表明该催化剂存在于立体化学反应中。确定 C-N 键形成步骤。
-
Preparation of Indolenines via Nucleophilic Aromatic Substitution作者:Florian Huber、Joel Roesslein、Karl GademannDOI:10.1021/acs.orglett.9b00489日期:2019.4.19An unusual aromatic substitution to access indolenines is described. 2-(2-Methoxyphenyl)acetonitrile derivatives are reacted with various alkyl and aryl Li reagents to furnish the corresponding indolenine products, constituents of natural products, and cyanine dyes such as indocyanine green. This new method was used to synthesize 41 indolenines with large functional group tolerance, and selected examples描述了一种不寻常的芳族取代基来取代吲哚。使2-(2-甲氧基苯基)乙腈衍生物与各种烷基和芳基Li试剂反应以提供相应的吲哚烯产物,天然产物的成分和花青染料,例如吲哚花青绿。该新方法用于合成具有较大官能团耐受性的41种吲哚胺,并将选定的实例进一步转化为相应的吲哚啉染料。关键实验提供了这种亲核芳族取代机理的见解。
-
Thieme Chemistry Journal Awardees - Where Are They Now? Asymmetric Brønsted Acid Catalyzed Transfer Hydrogenations作者:Magnus Rueping、Erli Sugiono、Fenja SchoepkeDOI:10.1055/s-0029-1219528日期:2010.4products under mild reaction conditions. 1 Introduction 2 Nature’s Reductions: Dehydrogenases as a Role Model 3 Bronsted Acid catalyzed Transfer Hydrogenation of Ketimines 4 Asymmetric Organocatalytic Reduction of Quinolines 5 Asymmetric Organocatalytic Reduction of N-Heterocycles 5.1 Asymmetric Bronsted Acid Catalyzed Hydrogenationof -Indoles 5.2 Asymmetric Bronsted Acid Catalyzed Hydrogenationof Benzoxazines不对称氢化在光学活性胺的合成中非常重要。该帐户重点介绍了第一个具有高度对映选择性并受自然界脱氢酶启发的无金属转移氢化反应的发展。进一步重点关注这种生物启发过程的扩展,以在温和的反应条件下提供各种有价值的生物活性产品和天然产品. 1 引言 2 自然还原:脱氢酶作为榜样 3 酮亚胺的布朗斯台德酸催化转移氢化 4 喹啉的不对称有机催化还原 5 N-杂环的不对称有机催化还原 5.1 不对称布朗斯台德酸催化氢化 - 吲哚 5.1 苯二氮唑的不对称布朗斯台德酸催化氢化反应, 苯并恶嗪酮类, 喹喔啉类,
-
Highly Enantioselective Synthesis of Indolines: Asymmetric Hydrogenation at Ambient Temperature and Pressure with Cationic Ruthenium Diamine Catalysts作者:Zhusheng Yang、Fei Chen、Yanmei He、Nianfa Yang、Qing-Hua FanDOI:10.1002/anie.201607890日期:2016.10.24asymmetric hydrogenation of 1H‐indoles and 3H‐indoles at ambient temperature and pressure, catalyzed by chiral phosphine‐free cationic ruthenium complexes, has been developed. Excellent enantio‐ and diastereoselectivities (up to >99 % ee, >20:1 d.r.) were obtained for a wide range of indole derivatives, including unprotected 2‐substituted and 2,3‐disubstituted 1H‐indoles, as well as 2‐alkyl‐ and 2‐aryl‐substituted已开发了在室温和压力下通过手性无膦膦阳离子钌络合物催化1 H吲哚和3 H吲哚的不对称氢化而高度合成对二氢吲哚的方法。优异的对映和非对映选择性(高达> 99%ee值,> 20:1,DR)被用于广泛的吲哚衍生物的获得,包括未受保护的2-取代和2,3-二取代的1个ħ -indoles,以及2-烷基和2-芳基取代的3 H-吲哚。
同类化合物
(Z)-3-[[[2,4-二甲基-3-(乙氧羰基)吡咯-5-基]亚甲基]吲哚-2--2-
(S)-(-)-5'-苄氧基苯基卡维地洛
(R)-(+)-5'-苄氧基卡维地洛
(R)-卡洛芬
(N-(Boc)-2-吲哚基)二甲基硅烷醇钠
(4aS,9bR)-6-溴-2,3,4,4a,5,9b-六氢-1H-吡啶并[4,3-B]吲哚
(3Z)-3-(1H-咪唑-5-基亚甲基)-5-甲氧基-1H-吲哚-2-酮
(3Z)-3-[[[4-(二甲基氨基)苯基]亚甲基]-1H-吲哚-2-酮
(3R)-(-)-3-(1-甲基吲哚-3-基)丁酸甲酯
(3-氯-4,5-二氢-1,2-恶唑-5-基)(1,3-二氧代-1,3-二氢-2H-异吲哚-2-基)乙酸
齐多美辛
鸭脚树叶碱
鸭脚木碱,鸡骨常山碱
鲜麦得新糖
高氯酸1,1’-二(十六烷基)-3,3,3’,3’-四甲基吲哚碳菁
马鲁司特
马来酸阿洛司琼
马来酸替加色罗
顺式-ent-他达拉非
顺式-1,3,4,4a,5,9b-六氢-2H-吡啶并[4,3-b]吲哚-2-甲酸乙酯
顺式-(+-)-3,4-二氢-8-氯-4'-甲基-4-(甲基氨基)-螺(苯并(cd)吲哚-5(1H),2'(5'H)-呋喃)-5'-酮
靛红联二甲酚
靛红磺酸钠
靛红磺酸
靛红乙烯硫代缩酮
靛红-7-甲酸甲酯
靛红-5-磺酸钠
靛红-5-磺酸
靛红-5-硫酸钠盐二水
靛红-5-甲酸甲酯
靛红
靛玉红3'-单肟5-磺酸
靛玉红-3'-单肟
靛玉红
青色素3联己酸染料,钾盐
雷马曲班
雷莫司琼杂质13
雷莫司琼杂质12
雷莫司琼杂质
雷替尼卜定
雄甾-1,4-二烯-3,17-二酮
阿霉素的代谢产物盐酸盐
阿贝卡尔
阿西美辛叔丁基酯
阿西美辛
阿莫曲普坦杂质1
阿莫曲普坦
阿莫曲坦二聚体杂质
阿莫曲坦
阿洛司琼杂质
联系我们
关注我们
公众号
