6-amino-3-methyl-4-(3-nitrophenyl)-1,4-dihydropyrano[2,3-c]pyrazole-5-carbonitrile | 81000-13-7
中文名称
——
中文别名
——
英文名称
6-amino-3-methyl-4-(3-nitrophenyl)-1,4-dihydropyrano[2,3-c]pyrazole-5-carbonitrile
英文别名
6-amino-3-methyl-4-(3-nitrophenyl)-2,4-dihydropyrano[2,3-c]pyrazole-5-carbonitrile;6-amino-1,4-dihydro-3-methyl-4-(3-nitrophenyl)pyrano[2,3-c]pyrazole-5-carbonitrile
![6-amino-3-methyl-4-(3-nitrophenyl)-1,4-dihydropyrano[2,3-c]pyrazole-5-carbonitrile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 0.90625 3.21875 L 0.90625 -12.8125 L 9.984375 -12.8125 L 9.984375 3.21875 Z M 1.921875 2.203125 L 8.984375 2.203125 L 8.984375 -11.796875 L 1.921875 -11.796875 Z M 1.921875 2.203125 "/>
</g>
<g id="glyph-0-1">
<path d="M 7.15625 -12.03125 C 5.851562 -12.03125 4.816406 -11.546875 4.046875 -10.578125 C 3.285156 -9.609375 2.90625 -8.285156 2.90625 -6.609375 C 2.90625 -4.941406 3.285156 -3.625 4.046875 -2.65625 C 4.816406 -1.6875 5.851562 -1.203125 7.15625 -1.203125 C 8.457031 -1.203125 9.488281 -1.6875 10.25 -2.65625 C 11.007812 -3.625 11.390625 -4.941406 11.390625 -6.609375 C 11.390625 -8.285156 11.007812 -9.609375 10.25 -10.578125 C 9.488281 -11.546875 8.457031 -12.03125 7.15625 -12.03125 Z M 7.15625 -13.484375 C 9.019531 -13.484375 10.503906 -12.859375 11.609375 -11.609375 C 12.722656 -10.367188 13.28125 -8.703125 13.28125 -6.609375 C 13.28125 -4.523438 12.722656 -2.859375 11.609375 -1.609375 C 10.503906 -0.367188 9.019531 0.25 7.15625 0.25 C 5.289062 0.25 3.800781 -0.367188 2.6875 -1.609375 C 1.570312 -2.847656 1.015625 -4.515625 1.015625 -6.609375 C 1.015625 -8.703125 1.570312 -10.367188 2.6875 -11.609375 C 3.800781 -12.859375 5.289062 -13.484375 7.15625 -13.484375 Z M 7.15625 -13.484375 "/>
</g>
<g id="glyph-0-2">
<path d="M 1.78125 -13.25 L 4.203125 -13.25 L 10.078125 -2.171875 L 10.078125 -13.25 L 11.8125 -13.25 L 11.8125 0 L 9.390625 0 L 3.515625 -11.078125 L 3.515625 0 L 1.78125 0 Z M 1.78125 -13.25 "/>
</g>
<g id="glyph-0-3">
<path d="M 1.78125 -13.25 L 3.578125 -13.25 L 3.578125 -7.8125 L 10.09375 -7.8125 L 10.09375 -13.25 L 11.875 -13.25 L 11.875 0 L 10.09375 0 L 10.09375 -6.3125 L 3.578125 -6.3125 L 3.578125 0 L 1.78125 0 Z M 1.78125 -13.25 "/>
</g>
<g id="glyph-0-4">
<path d="M 11.703125 -12.234375 L 11.703125 -10.34375 C 11.097656 -10.90625 10.453125 -11.320312 9.765625 -11.59375 C 9.085938 -11.875 8.363281 -12.015625 7.59375 -12.015625 C 6.082031 -12.015625 4.921875 -11.550781 4.109375 -10.625 C 3.304688 -9.695312 2.90625 -8.359375 2.90625 -6.609375 C 2.90625 -4.867188 3.304688 -3.535156 4.109375 -2.609375 C 4.921875 -1.679688 6.082031 -1.21875 7.59375 -1.21875 C 8.363281 -1.21875 9.085938 -1.351562 9.765625 -1.625 C 10.453125 -1.90625 11.097656 -2.328125 11.703125 -2.890625 L 11.703125 -1.015625 C 11.078125 -0.585938 10.410156 -0.269531 9.703125 -0.0625 C 9.003906 0.144531 8.265625 0.25 7.484375 0.25 C 5.484375 0.25 3.90625 -0.359375 2.75 -1.578125 C 1.59375 -2.804688 1.015625 -4.484375 1.015625 -6.609375 C 1.015625 -8.734375 1.59375 -10.410156 2.75 -11.640625 C 3.90625 -12.867188 5.484375 -13.484375 7.484375 -13.484375 C 8.273438 -13.484375 9.019531 -13.378906 9.71875 -13.171875 C 10.425781 -12.960938 11.085938 -12.648438 11.703125 -12.234375 Z M 11.703125 -12.234375 "/>
</g>
<g id="glyph-1-0">
<path d="M 0.609375 2.140625 L 0.609375 -8.546875 L 6.671875 -8.546875 L 6.671875 2.140625 Z M 1.28125 1.46875 L 5.984375 1.46875 L 5.984375 -7.875 L 1.28125 -7.875 Z M 1.28125 1.46875 "/>
</g>
<g id="glyph-1-1">
<path d="M 4.921875 -4.765625 C 5.492188 -4.640625 5.941406 -4.382812 6.265625 -4 C 6.585938 -3.613281 6.75 -3.132812 6.75 -2.5625 C 6.75 -1.695312 6.445312 -1.023438 5.84375 -0.546875 C 5.238281 -0.0664062 4.382812 0.171875 3.28125 0.171875 C 2.914062 0.171875 2.535156 0.132812 2.140625 0.0625 C 1.742188 -0.0078125 1.335938 -0.117188 0.921875 -0.265625 L 0.921875 -1.421875 C 1.253906 -1.222656 1.617188 -1.070312 2.015625 -0.96875 C 2.410156 -0.875 2.820312 -0.828125 3.25 -0.828125 C 4 -0.828125 4.566406 -0.972656 4.953125 -1.265625 C 5.347656 -1.566406 5.546875 -2 5.546875 -2.5625 C 5.546875 -3.082031 5.363281 -3.488281 5 -3.78125 C 4.632812 -4.082031 4.128906 -4.234375 3.484375 -4.234375 L 2.453125 -4.234375 L 2.453125 -5.21875 L 3.53125 -5.21875 C 4.113281 -5.21875 4.5625 -5.332031 4.875 -5.5625 C 5.1875 -5.800781 5.34375 -6.140625 5.34375 -6.578125 C 5.34375 -7.035156 5.179688 -7.382812 4.859375 -7.625 C 4.535156 -7.875 4.078125 -8 3.484375 -8 C 3.148438 -8 2.796875 -7.960938 2.421875 -7.890625 C 2.046875 -7.816406 1.632812 -7.703125 1.1875 -7.546875 L 1.1875 -8.625 C 1.644531 -8.75 2.070312 -8.84375 2.46875 -8.90625 C 2.863281 -8.96875 3.238281 -9 3.59375 -9 C 4.5 -9 5.210938 -8.789062 5.734375 -8.375 C 6.265625 -7.96875 6.53125 -7.410156 6.53125 -6.703125 C 6.53125 -6.210938 6.390625 -5.800781 6.109375 -5.46875 C 5.835938 -5.132812 5.441406 -4.898438 4.921875 -4.765625 Z M 4.921875 -4.765625 "/>
</g>
<g id="glyph-1-2">
<path d="M 2.328125 -1 L 6.5 -1 L 6.5 0 L 0.890625 0 L 0.890625 -1 C 1.335938 -1.476562 1.953125 -2.109375 2.734375 -2.890625 C 3.523438 -3.679688 4.019531 -4.191406 4.21875 -4.421875 C 4.601562 -4.859375 4.867188 -5.222656 5.015625 -5.515625 C 5.171875 -5.816406 5.25 -6.113281 5.25 -6.40625 C 5.25 -6.875 5.082031 -7.253906 4.75 -7.546875 C 4.425781 -7.847656 4 -8 3.46875 -8 C 3.09375 -8 2.695312 -7.929688 2.28125 -7.796875 C 1.863281 -7.671875 1.421875 -7.472656 0.953125 -7.203125 L 0.953125 -8.40625 C 1.429688 -8.601562 1.878906 -8.75 2.296875 -8.84375 C 2.710938 -8.945312 3.097656 -9 3.453125 -9 C 4.359375 -9 5.082031 -8.769531 5.625 -8.3125 C 6.175781 -7.851562 6.453125 -7.242188 6.453125 -6.484375 C 6.453125 -6.117188 6.382812 -5.769531 6.25 -5.4375 C 6.113281 -5.113281 5.863281 -4.734375 5.5 -4.296875 C 5.40625 -4.179688 5.09375 -3.847656 4.5625 -3.296875 C 4.03125 -2.753906 3.285156 -1.988281 2.328125 -1 Z M 2.328125 -1 "/>
</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 2.598327 2.002071 L 3.47276 1.495481 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 2.598327 2.002071 L 2.600304 3.011813 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 2.598327 2.002071 L 1.722863 1.499264 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 3.466313 1.499178 L 3.466313 0.501128 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 3.632999 1.37814 L 3.632999 0.622166 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 3.459264 1.496857 L 4.42353 1.8108 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 2.600304 3.002185 L 3.475769 3.504907 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 2.600734 3.194574 L 3.309256 3.601531 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 2.608643 2.997371 L 1.726817 3.509033 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 1.731201 1.504078 L 1.731201 0.501901 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 1.897887 1.407539 L 1.897887 0.598182 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 1.73954 1.499178 L 0.86631 2.006198 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 3.47276 0.504824 L 2.877713 0.159762 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 3.459264 0.503363 L 4.167527 0.273407 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 4.415449 1.808135 L 4.820171 1.250912 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 4.351836 1.612136 L 4.685293 1.152998 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 4.412871 1.800054 L 4.631049 2.471353 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 3.467431 3.49055 L 3.46915 4.509834 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 1.73507 3.494591 L 1.737219 4.51396 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 1.901927 3.590441 L 1.903646 4.417336 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 1.722863 0.506629 L 2.326421 0.158902 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 1.73954 0.506629 L 1.120078 0.149188 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 0.86631 2.006198 L 0.254843 2.359685 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 0.782924 1.861863 L 0.171457 2.215436 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 0.949782 2.150447 L 0.338315 2.504019 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 4.597781 0.443617 L 4.820085 0.749308 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 3.460811 4.495478 L 4.081477 4.851802 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 3.46915 4.500206 L 2.59592 5.007226 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 3.302292 4.404355 L 2.59549 4.814751 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 1.728794 4.499518 L 2.612597 5.00714 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 4.253664 5.25446 L 4.254438 5.736809 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 4.420263 5.254203 L 4.421123 5.736465 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 4.633112 4.922809 L 4.967601 4.72913 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<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 4.549554 4.77856 L 4.884043 4.584881 " transform="matrix(45.440155, 0, 0, 45.440155, 31.263636, 16.595875)"/>
<g fill="rgb(100%, 5.1%, 5.1%)" fill-opacity="1">
<use xlink:href="#glyph-0-1" x="142.355469" y="23.214844"/>
</g>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-0-2" x="225.105469" y="31.984375"/>
</g>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-0-3" x="225.070312" y="17.21875"/>
</g>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-0-2" x="251.773438" y="68.664062"/>
</g>
<g fill="rgb(0%, 0%, 0%)" fill-opacity="1">
<use xlink:href="#glyph-0-4" x="239.574219" y="148.539062"/>
</g>
<g fill="rgb(0%, 0%, 0%)" fill-opacity="1">
<use xlink:href="#glyph-0-3" x="251.007812" y="148.296875"/>
</g>
<g fill="rgb(0%, 0%, 0%)" fill-opacity="1">
<use xlink:href="#glyph-1-1" x="263.484375" y="149.339844"/>
</g>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-0-2" x="63.777344" y="23.316406"/>
</g>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-0-3" x="45.039062" y="23.316406"/>
</g>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-1-2" x="57.554688" y="24.355469"/>
</g>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-0-2" x="24.464844" y="137.140625"/>
</g>
<g fill="rgb(19%, 31%, 97.000003%)" fill-opacity="1">
<use xlink:href="#glyph-0-2" x="221.515625" y="250.34375"/>
</g>
<g fill="rgb(100%, 5.1%, 5.1%)" fill-opacity="1">
<use xlink:href="#glyph-0-1" x="221.242187" y="295.773438"/>
</g>
<g fill="rgb(100%, 5.1%, 5.1%)" fill-opacity="1">
<use xlink:href="#glyph-0-1" x="260.464844" y="227.574219"/>
</g>
</svg>
)
CAS
81000-13-7
化学式
C14H11N5O3
mdl
——
分子量
297.273
InChiKey
JBJAWVQREDWYEK-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
物化性质
-
熔点:232 °C(Solv: ethanol (64-17-5))
-
沸点:598.1±50.0 °C(Predicted)
-
密度:1.53±0.1 g/cm3(Predicted)
计算性质
-
辛醇/水分配系数(LogP):2.1
-
重原子数:22
-
可旋转键数:1
-
环数:3.0
-
sp3杂化的碳原子比例:0.14
-
拓扑面积:134
-
氢给体数:2
-
氢受体数:6
SDS
反应信息
-
作为反应物:描述:6-amino-3-methyl-4-(3-nitrophenyl)-1,4-dihydropyrano[2,3-c]pyrazole-5-carbonitrile 在 溶剂黄146 作用下, 以82 %的产率得到3-methyl-4-(3-nitrophenyl)-4,5-dihydro-1H-pyrano[2,3-c]pyrazol-6-one参考文献:名称:4-芳基稠合吡喃吡唑衍生物的合成和生物(体外和计算机)筛选,作为具有抗氧化和细胞毒性活性的酶(α-淀粉酶、α-葡萄糖苷酶、乙酰胆碱酯酶和蛋白酶)抑制剂摘要:开发针对双重/多种蛋白质的单一化合物是避免联合给药的有效方法。在此,基于先前报道的先导化合物A的修饰,我们合成了一系列新的二氢吡喃并吡唑酮7a-g和二氢吡唑并吡喃嘧啶-5-胺8。评估了这些化合物对α-淀粉酶的体外酶活性。 α-葡萄糖苷酶、乙酰胆碱酯酶和蛋白酶。此外,还对所有最终化合物进行了体外抗氧化剂评估和细胞毒性测定。有趣的是,与阿卡波糖(分别为 75.43 % 和 52.79 %)相比,化合物 8 对 α-淀粉酶(25.38 %)和 α-葡萄糖苷酶(29.37 %)具有中等活性。另一方面,与用作参考标准药物的多奈哌齐(67.28±0.61%)相比,化合物7f显示出中等的抗胆碱酯酶活性(46±0.03%抑制)。与用作参考的双氯芬酸钠(分别为47.93±0.01、44.96±0.02)相比,化合物7d表现出中等的抗关节炎活性(蛋白酶变性(42.21±0.04%)、蛋白酶抑制(38.09±0DOI:10.1016/j.molstruc.2024.138224
-
作为产物:描述:2-[(3-Methyl-5-oxo-4,5-dihydro-1H-pyrazol-4-yl)-(3-nitro-phenyl)-methyl]-malononitrile 在 吗啉 作用下, 以 甲醇 为溶剂, 以84%的产率得到6-amino-3-methyl-4-(3-nitrophenyl)-1,4-dihydropyrano[2,3-c]pyrazole-5-carbonitrile参考文献:名称:Sharanin, Yu. A.; Sharanina, L. G.; Puzanova, V. V., Journal of Organic Chemistry USSR (English Translation), 1983, p. 2291 - 2296摘要:DOI:
文献信息
-
Copper and nickel immobilized on cytosine@MCM‐41: as highly efficient, reusable and organic–inorganic hybrid nanocatalysts for the homoselective synthesis of tetrazoles and pyranopyrazoles作者:Mohsen Nikoorazm、Bahman Tahmasbi、Shahab Gholami、Parisa MoradiDOI:10.1002/aoc.5919日期:2020.11In this work, a green approach is reported for efficient synthesis of biologically active tetrazole and pyranopyrazole derivatives in the presence of Cu‐Cytosine@MCM‐41 and Ni‐Cytosine@MCM‐41 (copper (II) and nickel (II) catalyst on the modified MCM‐41 using cytosine). The synthesis of tetrazoles and pyranopyrazoles in the presence of these catalysts was performed in green solvents such as water or在这项工作中,报道了一种绿色方法,可以在存在Cu-Cytosine @ MCM-41和Ni-Cytosine @ MCM-41(铜(II)和镍(II)催化剂)的情况下有效合成具有生物活性的四唑和吡喃并吡唑衍生物。使用胞嘧啶修饰的MCM-41)。在这些催化剂的存在下,在绿色溶剂(例如水或聚(乙二醇)(PEG))中合成四唑和吡喃并吡唑。在这些催化剂的存在下,所有产品均以高TOF(周转频率)获得,这表明这些催化剂在合成四唑和吡喃并吡咯衍生物中具有很高的效率。所制备的催化剂通过各种技术进行表征,例如BET,TGA,XRD,FT-IR,SEM,EDS,WDX,TEM和AAS。这些催化剂的中孔结构通过氮吸附-解吸等温线得以证实。这些催化剂可以回收并重复使用几次,而其催化活性或金属容量没有明显变化。回收的催化剂已通过XRD,SEM,EDS,WDX,FT-IR和AAS技术进行了表征,从而证实了其非均相性质。
-
An approach to the synthesis and characterization of HMS/Pr-Rh-Zr as efficient catalyst for synthesis of tetrahydrobenzo[b]pyran and 1,4-dihydropyrano[2,3-c]pyrazole derivatives作者:Sahar Abdolahi、Maryam Hajjami、Fatemeh GholamianDOI:10.1007/s11164-021-04411-z日期:2021.5HMS/Pr-Rh-Zr was successfully synthesized. Also the catalytic activity of HMS/Pr-Rh-Zr is investigated for the synthesis of tetrahydrobenzo[b]pyran derivatives from reaction between aldehyde, malononitrile, dimedone in PEG at 80 °C and synthesis of 1,4-dihydropyrano[2,3-c]pyrazole derivatives from reaction between aldehyde, ethyl acetoacetate, malononitrile and hydrazine hydrate in H2O:EtOH at 35 °C本研究的目的是基于六角形介孔二氧化硅的介孔催化剂的合成。HMS支撑物具有出色的特性,例如易于合成,高表面积,大孔体积和虫孔。这些独特的特性似乎将其用作合成非均相催化剂的载体。通过HMS的功能化和将Zr-罗丹宁复合物固定到功能化的HMS中,获得了HMS / Pr-Rh-Zr。FT-IR,XRD,TGA,SEM,EDX,77 K氮气吸附-脱附和ICP技术表征了新型合成催化剂(HMS / Pr-Rh-Zr)。这些技术证实了成功地合成了HMS / Pr-Rh-Zr的非均相催化剂。还研究了HMS / Pr-Rh-Zr的催化活性,用于由醛之间的反应合成四氢苯并[b]吡喃衍生物。在35°C下2 O:EtOH。这些结果证实了HMS / Pr-Rh-Zr表现出良好的催化性能。此外,合成的非均相催化剂可以在反应后回收并重复使用几次而没有任何明显的活性损失。还研究了HMS / Pr-Rh-Zr的锆浸出,因此催化剂的金属浸出非常低。
-
Application of Yttrium Iron Garnet as a Powerful and Recyclable Nanocatalyst for One-Pot Synthesis of Pyrano[2,3-c]pyrazole Derivatives under Solvent-Free Conditions作者:E. Sedighinia、R. Badri、A. R. KiasatDOI:10.1134/s1070428019110186日期:2019.11The application of yttrium iron garnet (YIG) superparamagnetic nanoparticles as a new recyclable and highly efficient heterogeneous magnetic catalyst for one-pot synthesis of pyrano[2,3-c]pyrazole derivatives under solvent-free conditions, as well as etherification and esterification reactions are described. The advantages of the proposed method include the lack of organic solvents, clean reaction钇铁石榴石(YIG)超顺磁性纳米粒子作为新型可回收高效异质磁性催化剂在无溶剂条件下一锅合成吡喃并[2,3- c ]吡唑衍生物以及醚化和酯化反应的应用描述。所提出的方法的优点包括缺少有机溶剂,清洁的反应,催化剂的快速去除,短的反应时间,优异的产率和催化剂的可回收性。
-
Bovine serum albumin: An efficient and green biocatalyst for the one-pot four-component synthesis of pyrano[2,3-c]pyrazoles作者:Xingtian Huang、Zhipeng Li、Dongyang Wang、Yiqun LiDOI:10.1016/s1872-2067(15)61088-9日期:2016.9four-component reaction of aryl aldehydes, malononitrile, hydrazine hydrate, and ethyl acetoacetate for the synthesis of pyrano[2,3-c]pyrazoles under mild reaction conditions. The BSA biocatalyst also displayed a high catalytic affinity for acyclic/cyclic ketones to yield the corresponding pyrano[2,3-c]pyrazoles or their spirocyclic variants. The BSA could be used for at least five cycles without serious loss生物催化剂的使用在化学催化领域引起了越来越多的关注。在这里,我们已经证明,牛血清白蛋白 (BSA) 是一种普遍存在的、廉价的、非酶促转运蛋白,可以在芳基醛、丙二腈、水合肼、和乙酰乙酸乙酯用于在温和的反应条件下合成吡喃并[2,3-c]吡唑。BSA 生物催化剂还显示出对无环/环状酮的高催化亲和力,以产生相应的吡并 [2,3-c] 吡唑或其螺环变体。BSA 可以使用至少五个循环而不会严重损失催化活性。这种新颖、高效的协议具有产量高、操作简单和相对温和的环境影响等优点。而且,
-
Catalyst-free green synthesis of dihydropyrano[2,3-c]pyrazole scaffolds assisted by ethylene glycol (E-G) as a reusable and biodegradable solvent medium作者:Farzaneh MohamadpourDOI:10.1007/s12039-020-01775-4日期:2020.12green ethylene glycol (E-G) can be recycled at least six times with no considerable reduction in activity making it greatly advantageous in addressing the industrial requirements and environmental worries. Graphic AbstractThe catalyst-free and environmentally friendly synthesis of dihydropyrano[2,3-c]pyrazole scaffolds are reported via ethylene glycol (E-G) as a green, reusable and biodegradable promoting摘要我们发现无催化剂,绿色和快速一锅四部分串联的二氢吡喃并[2,3-的准备策略Ç ]吡唑-生物显著支架-通过Knoevenagel反应,迈克尔环合基于绿色化学原则。当前实践的重点是在无害反应条件下的应用,无催化剂,操作简便,使用廉价的引发剂,通过分离纯产物易于过滤,从而避免了对柱色谱法的需求,无金属,优异的收率,节省了反应时间。但是,绿色乙二醇(EG)可以循环使用至少六次,而活性不会显着降低,这使其在满足工业要求和环境问题方面具有极大优势。 图形摘要的二氢吡喃的和环境友好的无催化剂的合成[2,3- c ^ ]吡唑支架报告通过乙二醇(EG),为绿色,可重复使用的和可生物降解促进媒体经由乙酰乙酸乙酯,水合肼/的串联的Knoevenagel -迈克尔反应环化缩合苯肼,芳香族/脂肪族醛和丙二腈提供了预期的产品,具有出色的收率和较短的反应时间,这可能解决了工业上的一些成本问题
同类化合物
(βS)-β-氨基-4-(4-羟基苯氧基)-3,5-二碘苯甲丙醇
(S)-(-)-7'-〔4(S)-(苄基)恶唑-2-基]-7-二(3,5-二-叔丁基苯基)膦基-2,2',3,3'-四氢-1,1-螺二氢茚
(S)-盐酸沙丁胺醇
(S)-3-(叔丁基)-4-(2,6-二甲氧基苯基)-2,3-二氢苯并[d][1,3]氧磷杂环戊二烯
(S)-2,2'-双[双(3,5-三氟甲基苯基)膦基]-4,4',6,6'-四甲氧基联苯
(S)-1-[3,5-双(三氟甲基)苯基]-3-[1-(二甲基氨基)-3-甲基丁烷-2-基]硫脲
(R)富马酸托特罗定
(R)-(-)-盐酸尼古地平
(R)-(+)-7-双(3,5-二叔丁基苯基)膦基7''-[((6-甲基吡啶-2-基甲基)氨基]-2,2'',3,3''-四氢-1,1''-螺双茚满
(R)-3-(叔丁基)-4-(2,6-二苯氧基苯基)-2,3-二氢苯并[d][1,3]氧杂磷杂环戊烯
(R)-2-[((二苯基膦基)甲基]吡咯烷
(N-(4-甲氧基苯基)-N-甲基-3-(1-哌啶基)丙-2-烯酰胺)
(5-溴-2-羟基苯基)-4-氯苯甲酮
(5-溴-2-氯苯基)(4-羟基苯基)甲酮
(5-氧代-3-苯基-2,5-二氢-1,2,3,4-oxatriazol-3-鎓)
(4S,5R)-4-甲基-5-苯基-1,2,3-氧代噻唑烷-2,2-二氧化物-3-羧酸叔丁酯
(4-溴苯基)-[2-氟-4-[6-[甲基(丙-2-烯基)氨基]己氧基]苯基]甲酮
(4-丁氧基苯甲基)三苯基溴化磷
(3aR,8aR)-(-)-4,4,8,8-四(3,5-二甲基苯基)四氢-2,2-二甲基-6-苯基-1,3-二氧戊环[4,5-e]二恶唑磷
(2Z)-3-[[(4-氯苯基)氨基]-2-氰基丙烯酸乙酯
(2S,3S,5S)-5-(叔丁氧基甲酰氨基)-2-(N-5-噻唑基-甲氧羰基)氨基-1,6-二苯基-3-羟基己烷
(2S,2''S,3S,3''S)-3,3''-二叔丁基-4,4''-双(2,6-二甲氧基苯基)-2,2'',3,3''-四氢-2,2''-联苯并[d][1,3]氧杂磷杂戊环
(2S)-(-)-2-{[[[[3,5-双(氟代甲基)苯基]氨基]硫代甲基]氨基}-N-(二苯基甲基)-N,3,3-三甲基丁酰胺
(2S)-2-[[[[[[((1R,2R)-2-氨基环己基]氨基]硫代甲基]氨基]-N-(二苯甲基)-N,3,3-三甲基丁酰胺
(2-硝基苯基)磷酸三酰胺
(2,6-二氯苯基)乙酰氯
(2,3-二甲氧基-5-甲基苯基)硼酸
(1S,2S,3S,5S)-5-叠氮基-3-(苯基甲氧基)-2-[(苯基甲氧基)甲基]环戊醇
(1-(4-氟苯基)环丙基)甲胺盐酸盐
(1-(3-溴苯基)环丁基)甲胺盐酸盐
(1-(2-氯苯基)环丁基)甲胺盐酸盐
(1-(2-氟苯基)环丙基)甲胺盐酸盐
(-)-去甲基西布曲明
龙胆酸钠
龙胆酸叔丁酯
龙胆酸
龙胆紫
龙胆紫
齐达帕胺
齐诺康唑
齐洛呋胺
齐墩果-12-烯[2,3-c][1,2,5]恶二唑-28-酸苯甲酯
齐培丙醇
齐咪苯
齐仑太尔
黑染料
黄酮,5-氨基-6-羟基-(5CI)
黄酮,6-氨基-3-羟基-(6CI)
黄蜡,合成物
黄草灵钾盐
联系我们
关注我们
公众号
