地址:武汉市洪山区光谷大道35号光谷总部国际时代 二期1栋1301
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传真:18771997407
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艾美捷科技有限公司代理SIRIUS FINE CHEMICALS SICHEM GMBH公司产品。
SIRIUS FINE CHEMICALS SICHEM GMBH公司,主要提供:
点击化学工具(Si-CLICK (Click Chemistry))
PEG试剂(Si-PEGs)
脂质及其衍生物(Si-LIPs (Lipids & Derivatives))
磷酸肌醇试剂(Inositol Phosphates & Phosphoinositides)
核酸及其衍生物(Nucleotides & Derivatives)
API标准品及代谢底物(API Standards & Metabolites)
稳定的同位素(Stable Isotopes)
磷酸化及亚磷酸化试剂(Phosphorylation / Phosphitylation)
精细化学试剂(Fine Chemicals)
更多详情请联系
艾美捷科技有限公司
全国服务热线:400-6800-868
邮箱:sales@amyjet.com
网站:www.amyjet.com
产品列表
| 产品名称 | 产品编号 | 分子式 |
| Click Amino Acid / trans-Cyclooct-4-en – L - Lysine (TCO4/EQ) / EQUATORIAL isomer | SC-8060 | C15H26N2O4 |
| bifunctional Cross-Linking-Amino-Acid / PrDiAzK | SC-8028 | C13H20N4O5 |
| Click Amino Acid / exo-BCN – Fmoc – L - Lysine (BCN) | SC-8038 | C32H36N2O6 |
| Cross-Linking-Amino-Acid / DiAzK | SC-8034 | C11H20N4O4 |
| Click-Amino-Acid / N3-Lys | SC-8027 | C9H17N5O4 |
| Click Amino Acid / cyclopropene – L - Lysine (CP) | SC-8017 | C12H20N2O4 |
| Click Amino Acid / endo-BCN – Fmoc – L - Lysine (BCN) | SC-8015 | C32H36N2O6 |
| Click Amino Acid / trans-Cyclooct-2-en – L - Lysine (TCO*A) | SC-8008 | C15H26N2O4 |
| Click Amino Acid / exo BCN - L - Lysine | SC-8016 | C17H26N2O4 |
| Click Amino Acid / Norbonene-CH2 – L - Lysine (NBO) | SC-8006 | C15 H24 N2 O4 * HCl |
| Click Amino Acid / rac BCN - L - Lysine | SC-8003 | C17H26N2O4 |
| Click Amino Acid / trans-Cyclooct-4-en – L - Lysine (TCO4) / AXIAL isomer | SC-8004 | C15H26N2O4 |
| Click Amino Acid / endo BCN - L - Lysine | SC-8014 | C17H26N2O4 |
| Click-Amino-Acid / PrK - HCl-salt | SC-8002 | C10H16N2O4 * HCl |
| Click Amino Acid (99%) / SCO - L - Lysine - HCO2H-salt | SC-8001 | C15H24N2O4* HCO2H |
| Click Amino Acid (95%) / SCO - L - Lysine - HCO2H-salt | SC-8000 | C15H24N2O4 * HCO2H |
| SCO-NHS carbonate | SC-8076 | C13H15NO5 |
| exo-BCN-NHS carbonate | SC-8075 | C15H17NO5 |
| endo-BCN-NHS carbonate | SC-8074 | C15H17NO5 |
| SCO-PEG7-Maleimide | SC-8305 | C32H51N3O12 |
| SCO-PEG3-Maleimide | SC-8304 | C24H35N3O8 |
| SCO-PEG2-Maleimide | SC-8303 | C22H31N3O7 |
| BCN-exo-PEG7-Maleimide | SC-8205 | C34H53N3O12 |
| BCN-exo-PEG3-Maleimide | SC-8204 | C24H33N3O7 |
| BCN-exo-PEG2-Maleimide | SC-8203 | C24H33N3O7 |
| BCN-endo-PEG7-Maleimide | SC-8105 | C34H53N3O12 |
| BCN-endo-PEG3-Maleimide | SC-8104 | C24H33N3O7 |
| BCN-endo-PEG2-Maleimide | SC-8103 | C24H33N3O7 |
| BCN-exo-PEG8-COOH | SC-8211 | C30H51NO12 |
| BCN-exo-PEG4-COOH | SC-8210 | C22H35NO8 |
| BCN-exo-PEG3-COOH | SC-8209 | C20H31NO7 |
| BCN-exo-PEG8-NHS | SC-8208 | C34H54N2O14 |
| BCN-exo-PEG4-NHS | SC-8207 | C26H38N2O10 |
| BCN-exo-PEG3-NHS | SC-8206 | C24H34N2O9 |
| BCN-endo-PEG3-NHS | SC-8106 | C24H34N2O9 |
| BCN-endo-PEG4-NHS | SC-8107 | C26H38N2O10 |
| BCN-endo-PEG8-NHS | SC-8108 | C34H54N2O14 |
| BCN-endo-PEG8-COOH | SC-8111 | C30H51NO12 |
| BCN-endo-PEG4-COOH | SC-8110 | C22H35NO8 |
| BCN-endo-PEG3-COOH | SC-8109 | C20H31NO7 |
| SCO-PEG3-COOH | SC-8309 | C18H29NO7 |
| SCO-PEG4-COOH | SC-8310 | C20H33NO8 |
| SCO-PEG8-COOH | SC-8311 | C28H49NO12 |
| SCO-PEG8-NHS | SC-8308 | C32H52N2O14 |
| SCO-PEG4-NHS | SC-8307 | C24H36N2O10 |
| SCO-PEG3-NHS | SC-8306 | C22H32N2O9 |
| SCO-PEG7-NH2 | SC-8302 | C25H46N2O9 |
| SCO-PEG3-NH2 | SC-8301 | C17H30N2O5 |
| SCO-PEG2-NH2 | SC-8300 | C15H26N2O4 |
| BCN-exo-PEG2-NH2 | SC-8200 | C17H28N2O4 |
| BCN-exo-PEG3-NH2 | SC-8201 | C19H32N2O5 |
| BCN-exo-PEG7-NH2 | SC-8202 | C27H48N2O9 |
| BCN-endo-PEG7-NH2 | SC-8102 | C27H48N2O9 |
| BCN-endo-PEG3-NH2 | SC-8101 | C19H32N2O5 |
| BCN-endo-PEG2-NH2 | SC-8100 | C17H28N2O4 |
| exo BCN - OH | SC-8033 | C10 H14 O |
| SCO - active ester (p-NPE) | SC-8032 | C15H15NO5 |
| SCO - OH | SC-8030 | C8H12O |
| endo BCN - OH | SC-8029 | C10 H14 O |
| exo BCN - active ester (p-NPE) | SC-8010 | C17H17NO5 |
| TCO4 - NHS carbonate / EQUATORIAL isomer | SC-8073 | C13H17NO5 |
| TCO4 - NHS carbonate / AXIAL isomer | SC-8072 | C13H17NO5 |
| (E)-cyclooct-4-enol / axial - TCO4 / A | SC-8018 | C8H14O |
| TCO4-PEG8-COOH | SC-8411 | C28H51NO12 |
| TCO*-PEG8-COOH | SC-8511 | C28H51NO12 |
| TCO*-PEG4-COOH | SC-8510 | C20H35NO8 |
| TCO4-PEG4-COOH | SC-8410 | C20H35NO8 |
| TCO4-PEG3-COOH | SC-8409 | C18H31NO7 |
| TCO*-PEG3-COOH | SC-8509 | C20H31NO7 |
| TCO*-PEG8-NHS | SC-8508 | C32H54N2O14 |
| TCO4-PEG8-NHS | SC-8408 | C32H54N2O14 |
| TCO4-PEG4-NHS | SC-8407 | C24H38N2O10 |
| TCO*-PEG4-NHS | SC-8507 | C24H38N2O10 |
| TCO*-PEG3-NHS | SC-8506 | C22H34N2O9 |
| TCO4-PEG3-NHS | SC-8406 | C22H34N2O9 |
| TCO*-PEG7-Maleimide | SC-8505 | C32H53N3O12 |
| TCO*-PEG3-Maleimide | SC-8504 | C24H37N3O8 |
| TCO*-PEG2-Maleimide | SC-8503 | C22H33N3O7 |
| TCO4-PEG7-Maleimide | SC-8405 | C32H53N3O12 |
| TCO4-PEG3-Maleimide | SC-8404 | C24H37N3O8 |
| TCO4-PEG2-Maleimide | SC-8403 | C22H33N3O7 |
| TCO*-PEG2-NH2 | SC-8500 | C15H28N2O4 |
| TCO*-PEG3-NH2 | SC-8501 | C17H32N2O5 |
| TCO*-PEG7-NH2 | SC-8502 | C25H48N2O9 |
| TCO4-PEG7-NH2 | SC-8402 | C25H48N2O9 |
| TCO4-PEG3-NH2 | SC-8401 | C17H32N2O5 |
| TCO4-PEG2-NH2 | SC-8400 | C15H28N2O4 |
| (E)-cyclooct-4-en active ester / TCO/E- active ester (p-NPE) / equatorial | SC-8024 | C15H17NO5 |
| (E)-cyclooct-4-en active ester / TCO4 / A- active ester (p-NPE) / axial | SC-8019 | C15H17NO5 |
| TCO*A - active ester (p-NPE) | SC-8007 | C15H17NO5 |
| Fluorescent-PEG8-Me-Tet | SC-8817 | C54H68N8O13 |
| Fluorescent-PEG4-Me-Tet | SC-8816 | C46H52N8O9 |
| Fluorescent-PEG3-Me-Tet | SC-8815 | C44H48N8O8 |
| Me-Tet-PEG8-NHBoc | SC-8820 | C34H56N6O11 |
| Me-Tet-PEG4-NHBoc | SC-8819 | C26H40N6O7 |
| Me-Tet-PEG3-NHBoc | SC-8818 | C24H36N6O6 |
| Biotin-PEG8-Me-Tet | SC-8814 | C39H62N8O11S |
| Biotin-PEG4-Me-Tet | SC-8813 | C31H46N8O7S |
| Biotin-PEG3-Me-Tet | SC-8812 | C29H42N8O6S |
| Me-Tet-PEG9-COOH | SC-8811 | C32H51N5O12 |
| Me-Tet-PEG5-COOH | SC-8810 | C24H35N5O8 |
| Me-Tet-PEG4-COOH | SC-8809 | C22H31N5O7 |
| Me-Tet-PEG9-NHS | SC-8808 | C36H54N6O14 |
| Me-Tet-PEG5-NHS | SC-8807 | C28H38N6O10 |
| Me-Tet-PEG4-NHS | SC-8806 | C26H34N6O9 |
| Me-Tet-PEG8-Maleimide | SC-8805 | C36H53N7O12 |
| Me-Tet-PEG4-Maleimide | SC-8804 | C28H37N7O8 |
| Me-Tet-PEG3-Maleimide | SC-8803 | C26H33N7O7 |
| Me-Tet-PEG8-NH2 - HCl salt | SC-8802 | C29H48N6O9 + HCl |
| Me-Tet-PEG4-NH2 | SC-8801 | C21H32N6O5 |
| Me-Tet-PEG3-NH2 | SC-8800 | C19H28N6O4 |
| Aminopentyl - Tetrazine - HCl-salt | SC-1193 | C18H20N8O * HCl |
| Tetrazine active ester (Tetrazine-NHS) | SC-1194 | C17H11N7O4 |
| Aminopropyl - Tetrazine - HCl-salt | SC-1192 | C16H16N8O * HCl |
| Methyl-Tetrazine - Amine- HCO2H-salt | SC-1191 | C10H11N5* HCO2H |
| Tetrazine - Amine - HCO2H-salt | SC-1190 | C9H9N5 * HCO2H |
| N3-PEG8-t-butyl ester | SC-8923 | C23H45N3O10 |
| N3-PEG5-t-butyl ester | SC-8922 | C17H33N3O7 |
| N3-PEG4-t-butyl ester | SC-8921 | C15H29N3O6 |
| N3-PEG3-t-butyl ester | SC-8920 | C13H25N3O5 |
| Boc-N-Amido-PEG7-N3 | SC-8912 | C21H42N4O9 |
| Boc-N-Amido-PEG3-N3 | SC-8911 | C13H26N4O5 |
| Boc-N-Amido-PEG2-N3 | SC-8910 | C11H22N4O4 |
| Boc-N-Amido-PEG4-Alkyne | SC-8900 | C16H29NO6 |
| Boc-N-Amido-PEG3-Alkyne | SC-8039 | C14H25NO5 |
| TAMRA-PEG8-Alkyne | SC-8717 | C44H57N3O12 |
| TAMRA-PEG4-Alkyne | SC-8716 | C36H41N3O8 |
| TAMRA-PEG3-Alkyne | SC-8715 | C34H37N3O7 |
| TAMRA-PEG7-N3 | SC-8714 | C41H54N6O11 |
| TAMRA-PEG3-N3 | SC-8713 | C33H38N6O7 |
| TAMRA-PEG2-N3 | SC-8712 | C31H34N6O6 |
| Biotin-PEG8-Alkyne | SC-8617 | C29H51N3O10S |
| Biotin-PEG4-Alkyne | SC-8616 | C21H35N3O6S |
| Biotin-PEG3-Alkyne | SC-8615 | C19H31N3O5S |
| Biotin-PEG7-N3 | SC-8614 | C26H48N6O9S |
| Biotin-PEG3-N3 | SC-8613 | C18H32N6O5S |
| Biotin-PEG2-N3 | SC-8612 | C16H28N6O4S |
| Click-Amino-Acid / PrK - HCl-salt | SC-8002 | C10H16N2O4 * HCl |
| Alkyne - PEG2 | SC-0063 | C7H12O3 |
| Azido - PEG1 | SC-0062 | C4H9N3O2 |
| Biotin-PEG8-Alkyne | SC-8617 | C29H51N3O10S |
| Biotin-PEG4-Alkyne | SC-8616 | C21H35N3O6S |
| Biotin-PEG3-Alkyne | SC-8615 | C19H31N3O5S |
| Alkyne - PEG2 - TCA | SC-0067 | C9H12Cl3NO3 |
| Alkyne - PEG2 - CM | SC-0065 | C8H13ClO3 |
| Alkyne - PEG2 | SC-0063 | C7H12O3 |
| TAMRA-PEG7-N3 | SC-8714 | C41H54N6O11 |
| TAMRA-PEG3-N3 | SC-8713 | C33H38N6O7 |
| TAMRA-PEG2-N3 | SC-8712 | C31H34N6O6 |
| Biotin-PEG7-N3 | SC-8614 | C26H48N6O9S |
| Biotin-PEG3-N3 | SC-8613 | C18H32N6O5S |
| Biotin-PEG3-CoenzymeA | SC-8618 | C46H75N12O24P3S2+3NH3 |
| Bis-Cyano-PEG9 | SC-8932 | C22H40N2O9 |
| Bis-Cyano-PEG5 | SC-8931 | C14H24N2O5 |
| Bis-Cyano-PEG4 | SC-8930 | C12H20N2O4 |
| N3-PEG8-t-butyl ester | SC-8923 | C23H45N3O10 |
| N3-PEG5-t-butyl ester | SC-8922 | C17H33N3O7 |
| N3-PEG4-t-butyl ester | SC-8921 | C15H29N3O6 |
| N3-PEG3-t-butyl ester | SC-8920 | C13H25N3O5 |
| Boc-N-Amido-PEG7-N3 | SC-8912 | C21H42N4O9 |
| Boc-N-Amido-PEG3-N3 | SC-8911 | C13H26N4O5 |
| Boc-N-Amido-PEG2-N3 | SC-8910 | C11H22N4O4 |
| Boc-N-Amido-PEG4-Alkyne | SC-8900 | C16H29NO6 |
| Boc-N-Amido-PEG3-Alkyne | SC-8039 | C14H25NO5 |
| Fluorescent-PEG8-Me-Tet | SC-8817 | C54H68N8O13 |
| Fluorescent-PEG4-Me-Tet | SC-8816 | C46H52N8O9 |
| Fluorescent-PEG3-Me-Tet | SC-8815 | C44H48N8O8 |
| TAMRA-PEG8-Alkyne | SC-8717 | C44H57N3O12 |
| TAMRA-PEG4-Alkyne | SC-8716 | C36H41N3O8 |
| TAMRA-PEG3-Alkyne | SC-8715 | C34H37N3O7 |
| TAMRA-PEG7-N3 | SC-8714 | C41H54N6O11 |
| TAMRA-PEG3-N3 | SC-8713 | C33H38N6O7 |
| TAMRA-PEG2-N3 | SC-8712 | C31H34N6O6 |
| TAMRA-PEG8-COOH | SC-8711 | C44H59N3O14 |
| TAMRA-PEG4-COOH | SC-8710 | C36H43N3O10 |
| TAMRA-PEG3-COOH | SC-8709 | C34H39N3O9 |
| TAMRA-PEG8-NHS | SC-8708 | C48H62N4O16 |
| TAMRA-PEG4-NHS | SC-8707 | C40H46N4O12 |
| TAMRA-PEG3-NHS | SC-8706 | C38H42N4O11 |
| TAMRA-PEG7-Maleimide | SC-8705 | C48H61N5O14 |
| TAMRA-PEG3-Maleimide | SC-8704 | C40H45N5O10 |
| TAMRA-PEG2-Maleimide | SC-8703 | C38H41N5O9 |
| TAMRA-PEG7-NH2 | SC-8702 | C41H56N4O11 |
| TAMRA-PEG3-NH2 | SC-8701 | C33H40N4O7 |
| TAMRA-PEG2-NH2 | SC-8700 | C31H36N4O6 |
| Me-Tet-PEG8-NHBoc | SC-8820 | C34H56N6O11 |
| Me-Tet-PEG4-NHBoc | SC-8819 | C26H40N6O7 |
| Me-Tet-PEG3-NHBoc | SC-8818 | C24H36N6O6 |
| Biotin-PEG8-Me-Tet | SC-8814 | C39H62N8O11S |
| Biotin-PEG4-Me-Tet | SC-8813 | C31H46N8O7S |
| Biotin-PEG3-Me-Tet | SC-8812 | C29H42N8O6S |
| Me-Tet-PEG9-COOH | SC-8811 | C32H51N5O12 |
| Me-Tet-PEG5-COOH | SC-8810 | C24H35N5O8 |
| Me-Tet-PEG4-COOH | SC-8809 | C22H31N5O7 |
| Me-Tet-PEG9-NHS | SC-8808 | C36H54N6O14 |
| Me-Tet-PEG5-NHS | SC-8807 | C28H38N6O10 |
| Me-Tet-PEG4-NHS | SC-8806 | C26H34N6O9 |
| Me-Tet-PEG8-Maleimide | SC-8805 | C36H53N7O12 |
| Me-Tet-PEG4-Maleimide | SC-8804 | C28H37N7O8 |
| Me-Tet-PEG3-Maleimide | SC-8803 | C26H33N7O7 |
| Me-Tet-PEG8-NH2 - HCl salt | SC-8802 | C29H48N6O9 + HCl |
| Me-Tet-PEG4-NH2 | SC-8801 | C21H32N6O5 |
| Me-Tet-PEG3-NH2 | SC-8800 | C19H28N6O4 |
| Biotin-PEG8-Alkyne | SC-8617 | C29H51N3O10S |
| Biotin-PEG4-Alkyne | SC-8616 | C21H35N3O6S |
| Biotin-PEG3-Alkyne | SC-8615 | C19H31N3O5S |
| Biotin-PEG7-N3 | SC-8614 | C26H48N6O9S |
| Biotin-PEG3-N3 | SC-8613 | C18H32N6O5S |
| Biotin-PEG2-N3 | SC-8612 | C16H28N6O4S |
| Biotin-PEG8-COOH | SC-8611 | C29H53N3O12S |
| Biotin-PEG4-COOH | SC-8610 | C19H33N3O7S |
| Biotin-PEG3-COOH | SC-8609 | C19H33N3O7S |
| Biotin-PEG8-NHS | SC-8608 | C33H56N4O14S |
| Biotin-PEG4-NHS | SC-8607 | C25H40N4O10S |
| Biotin-PEG3-NHS | SC-8606 | C23H36N4O9S |
| Biotin-PEG7-Maleimide | SC-8605 | C33H55N5O12S |
| Biotin-PEG3-Maleimide | SC-8604 | C25H39N5O8S |
| Biotin-PEG2-Maleimide | SC-8603 | C23H35N5O7S |
| Biotin-PEG7-NH2 | SC-8602 | C26H50N4O9S |
| Biotin-PEG3-NH2 | SC-8601 | C18H34N4O5S |
| Biotin-PEG2-NH2 | SC-8600 | C16H30N4O4S |
| TCO4-PEG8-COOH | SC-8411 | C28H51NO12 |
| TCO*-PEG8-COOH | SC-8511 | C28H51NO12 |
| TCO*-PEG4-COOH | SC-8510 | C20H35NO8 |
| TCO4-PEG4-COOH | SC-8410 | C20H35NO8 |
| TCO4-PEG3-COOH | SC-8409 | C18H31NO7 |
| TCO*-PEG3-COOH | SC-8509 | C20H31NO7 |
| TCO*-PEG8-NHS | SC-8508 | C32H54N2O14 |
| TCO4-PEG8-NHS | SC-8408 | C32H54N2O14 |
| TCO4-PEG4-NHS | SC-8407 | C24H38N2O10 |
| TCO*-PEG4-NHS | SC-8507 | C24H38N2O10 |
| TCO*-PEG3-NHS | SC-8506 | C22H34N2O9 |
| TCO4-PEG3-NHS | SC-8406 | C22H34N2O9 |
| TCO*-PEG7-Maleimide | SC-8505 | C32H53N3O12 |
| TCO*-PEG3-Maleimide | SC-8504 | C24H37N3O8 |
| TCO*-PEG2-Maleimide | SC-8503 | C22H33N3O7 |
| TCO4-PEG7-Maleimide | SC-8405 | C32H53N3O12 |
| TCO4-PEG3-Maleimide | SC-8404 | C24H37N3O8 |
| TCO4-PEG2-Maleimide | SC-8403 | C22H33N3O7 |
| TCO*-PEG2-NH2 | SC-8500 | C15H28N2O4 |
| TCO*-PEG3-NH2 | SC-8501 | C17H32N2O5 |
| TCO*-PEG7-NH2 | SC-8502 | C25H48N2O9 |
| TCO4-PEG7-NH2 | SC-8402 | C25H48N2O9 |
| TCO4-PEG3-NH2 | SC-8401 | C17H32N2O5 |
| TCO4-PEG2-NH2 | SC-8400 | C15H28N2O4 |
| SCO-PEG7-Maleimide | SC-8305 | C32H51N3O12 |
| SCO-PEG3-Maleimide | SC-8304 | C24H35N3O8 |
| SCO-PEG2-Maleimide | SC-8303 | C22H31N3O7 |
| BCN-exo-PEG7-Maleimide | SC-8205 | C34H53N3O12 |
| BCN-exo-PEG3-Maleimide | SC-8204 | C24H33N3O7 |
| BCN-exo-PEG2-Maleimide | SC-8203 | C24H33N3O7 |
| BCN-endo-PEG7-Maleimide | SC-8105 | C34H53N3O12 |
| BCN-endo-PEG3-Maleimide | SC-8104 | C24H33N3O7 |
| BCN-endo-PEG2-Maleimide | SC-8103 | C24H33N3O7 |
| BCN-exo-PEG8-COOH | SC-8211 | C30H51NO12 |
| BCN-exo-PEG4-COOH | SC-8210 | C22H35NO8 |
| BCN-exo-PEG3-COOH | SC-8209 | C20H31NO7 |
| BCN-exo-PEG8-NHS | SC-8208 | C34H54N2O14 |
| BCN-exo-PEG4-NHS | SC-8207 | C26H38N2O10 |
| BCN-exo-PEG3-NHS | SC-8206 | C24H34N2O9 |
| BCN-endo-PEG3-NHS | SC-8106 | C24H34N2O9 |
| BCN-endo-PEG4-NHS | SC-8107 | C26H38N2O10 |
| BCN-endo-PEG8-NHS | SC-8108 | C34H54N2O14 |
| BCN-endo-PEG8-COOH | SC-8111 | C30H51NO12 |
| BCN-endo-PEG4-COOH | SC-8110 | C22H35NO8 |
| BCN-endo-PEG3-COOH | SC-8109 | C20H31NO7 |
| SCO-PEG3-COOH | SC-8309 | C18H29NO7 |
| SCO-PEG4-COOH | SC-8310 | C20H33NO8 |
| SCO-PEG8-COOH | SC-8311 | C28H49NO12 |
| SCO-PEG8-NHS | SC-8308 | C32H52N2O14 |
| SCO-PEG4-NHS | SC-8307 | C24H36N2O10 |
| SCO-PEG3-NHS | SC-8306 | C22H32N2O9 |
| SCO-PEG7-NH2 | SC-8302 | C25H46N2O9 |
| SCO-PEG3-NH2 | SC-8301 | C17H30N2O5 |
| SCO-PEG2-NH2 | SC-8300 | C15H26N2O4 |
| BCN-exo-PEG2-NH2 | SC-8200 | C17H28N2O4 |
| BCN-exo-PEG3-NH2 | SC-8201 | C19H32N2O5 |
| BCN-exo-PEG7-NH2 | SC-8202 | C27H48N2O9 |
| BCN-endo-PEG7-NH2 | SC-8102 | C27H48N2O9 |
| BCN-endo-PEG3-NH2 | SC-8101 | C19H32N2O5 |
| BCN-endo-PEG2-NH2 | SC-8100 | C17H28N2O4 |
| PEG-12 | SC-1512 | C24H50O13 |
| PEG-11 | SC-1511 | C22H46O12 |
| PEG-10 | SC-1510 | C20H42O11 |
| PEG-9 | SC-1509 | C18H38O10 |
| PEG-8 | SC-1508 | C16H34O9 |
| Alkyne - PEG2 - TCA | SC-0067 | C9H12Cl3NO3 |
| Azido - PEG2 - TCA | SC-0066 | C6H9Cl3N4O2 |
| Alkyne - PEG2 - CM | SC-0065 | C8H13ClO3 |
| Azido - PEG2 - CM | SC-0064 | C5H10ClN3O |
| Alkyne - PEG2 | SC-0063 | C7H12O3 |
| Azido - PEG1 | SC-0062 | C4H9N3O2 |
| 2-Methyl-Glycerol | SC-0006 | C4H10O3 |
| 2-Stearoyl glycerol | SC-1171 | C21H42O4 |
| 2-Palmitoyl glycerol | SC-1170 | C19H38O4 |
| 2-Myristoyl glycerol | SC-1169 | C17H34O4 |
| 2-Lauroyl glycerol | SC-1168 | C15H30O4 |
| 2-Linoleoyl glycerol | SC-1167 | C21H38O4 |
| 2-Oleoyl-glycerol | SC-1162 | C21H40O4 |
| SH-6 | SC-0045 | C28H57O9P |
| SH-5 | SC-0044 | C29H59O10P |
| Ins(345)P3*3Na | 3-0-345-Na | C6H12Na3O15P3 |
| Ins(1)P*2K | 1-0-1-2K | C6H11K2O9P |
| myo-Inositol – trispyrophosphate | Pyro-Ins-Na | C6H8Na4O21P6 |
| Ins(123456)P6 | 6-0-123456-Na | C6H18O24P6 * xNa*yH2O |
| Ins(23456)P5*10Na | 5-0-23456-Na | C6H7Na10O21P5 |
| Ins(13456)P5*10Na | 5-0-13456-Na | C6H7Na10O21P5 |
| Ins(12456)P5*10Na | 5-0-12456-Na | C6H7Na10O21P5 |
| Ins(12356)P5*10Na | 5-0-12356-Na | C6H7Na10O21P5 |
| Ins(12345)P5*10Na | 5-0-12345-Na | C6H7Na10O21P5 |
| Ins(1345)P4*8Na | 4-0-1345-Na | C6H8Na8O18P4 |
| Ins(136)P3*6Na | 3-0-136-Na | C6H9Na6O15P3 |
| Ins(134)P3*6K | 3-0-134-K | C6H9K6O15P3 |
| Ins(345)P3*3K | 3-0-345-K | C6H12K3O15P3 |
| Ins(145)P3*6K | 3-0-145-K | C6H9K6O15P3 |
| Ins(145)P3*3Li | 3-0-145-Li | C6H12Li3O15P3 |
| Ins(145)P3*6Na | 3-0-145-Na | C6H9Na6O15P3 |
| Ins(135)P3*6Na | 3-0-135-6Na | C6H9Na6O15P3 |
| Ins(1245)P4*8Na | 4-0-1245-Na | C6H8Na8O18P4 |
| INO-4995 | INO-4995 | C50H86O35P4 |
| Bt3-Ins(356)P3 / PM | 3-2-356 | C42H69O30P3 |
| Bt3-Ins(346)P3 / PM | 3-2-346 | C42H69O30P3 |
| Bt3-Ins(146)P3 / PM | 3-2-146 | C42H69O30P3 |
| Bt3-Ins(135)P3 / PM | 3-2-135 | C42H69O30P3 |
| caged-Ins(145)P3 / PM | cag-iso-2-145-10 | C42H64NO31P3 |
| caged-Ins(145)P3 / PM | cag-iso-2-145-100 | C42H64NO31P3 |
| Bt2-Ins(3456)P4 / PM | 4-2-3456 | C46H76O36P4 |
| Bt2-Ins(1456)P4 / PM | 4-2-1456 | C46H76O36P4 |
| Bt2-Ins(1345)P4 / PM | 4-2-1345 | C46H76O36P4 |
| Bt2-Ins(1356)P4 / AM | 4-1-1356 | C38H60O36P4 |
| Bt3-Ins(356)P3 / AM | 3-1-356 | C36H57O30P3 |
| Bt3-Ins(346)P3 / AM | 3-1-346 | C36H57O30P3 |
| Bt3-Ins(146)P3 / AM | 3-1-146 | C36H57O30P3 |
| Bt3-Ins(134)P3 / AM | 3-1-134 | C36H57O30P3 |
| Bt3-Ins(136)P3 / AM | 3-1-136 | C36H57O30P3 |
| Bt3-Ins(135)P3 / AM | 3-1-135 | C36H57O30P3 |
| Bt3-Ins(145)P3 / AM | 3-1-145 | C36H57O30P3 |
| caged-Ins(145)P3 / PM | cag-iso-2-145-10 | C42H64NO31P3 |
| caged-Ins(145)P3 / PM | cag-iso-2-145-100 | C42H64NO31P3 |
| caged-Ins(145)P3O6 | cag-6-145 | C15H18NO19P3Na6 |
| caged-Ins(145)P3 P4 | cag-0-145 | C14H19NO17P3Na3 |
| PtdIns(345)P3 | Ptd-0-345-16 | C41H82O22P4 |
| PtdIns(45)P2 | Ptd-0-45-16 | C41H81O19P3 |
| PtdIns(34)P2 | Ptd-0-34-16 | C41H81O19P3 |
| PtdIns(5)P | Ptd-0-5-16 | C41H80O16P2 |
| PtdIns(4)P | Ptd-0-4-16 | C41H80O16P2 |
| PtdIns(3)P | Ptd-0-3-16 | C41H80O16P2 |
| PtdIns(1)P | Ptd-0-1-16 | C41H79O13P |
| D-myo-Inositol-1,2-O-cyclohexylidene | SC-0088 | C12H20O6 |
| 23:45- diisopropylidene-myo-Inositol | SC-0079 | C12H20O6 |
| 12:56- diisopropylidene-myo-Inositol | SC-0078 | C12H20O6 |
| D-myo-Inositol-2,3-O-cyclohexylidene | SC-0077 | C12H20O6 |
| 1,4-Di-butyryl-23:56-diisopropylidene-myo-Inositol | SC-0076 | C20H32O8 |
| 3,6-Di-butyryl-12:45-diisopropylidene-myo-Inositol | SC-0075 | C20H32O8 |
| 2,3:4,5-Di-O-Iso-1,6-Di-O-Benzyl-Ins | IOB-Ins-2345 | C26H32O6 |
| 1,2:5,6-Di-O-Iso-3,4-Di-O-Benzyl-Ins | IOB-Ins-1256 | C26H32O6 |
| 3,4,5,6-Tetra-O-Benzyl-Ins | TOB-Ins-3456 | C34H36O6 |
| 1,4,5,6-Tetra-O-Benzyl-Ins | TOB-Ins-1456 | C34H36O6 |
| DEAC-dUTP | SC-9002 | C26H31N4O17P3 |
| 35-PAPS-TEA | SC-9000-TEA | C10H15N5O13P2S x 4 C6 H15 N |
| ACPPS-TEA | SC-0068 | C10H13N5O12P2S + C6H5N |
| 25-PAPS-Li | SC-9001-Li | C10H11Li4N5O13P2S |
| 35-PAPS-Li (CAS: 102029-54-9) | SC-9000-Li | C10H11Li4N5O13P2S |
| EdU | SC-0040 | C11H12N2O5 |
| EdUTP-TEA | SC-0039 | C11H15N2O14P3 * 4(C6H15N) |
| EdUTP | SC-0038 | C11H15N2O14P3 |
| 2'-PAP | SC-0037 | C10H17N5O10P2 |
| 2'-PAP-Na | SC-0036 | C10H15N5Na2O10P2 |
| 3'-PAP-Na | SC-0034 | C10H15N5Na2O10P2 |
| 3'-PAP | SC-0035 | C10H17N5O10P2 |
| Vancomycin hexapeptide | SC-1606 | C59H62Cl2N8O23 |
| Didechloro Vancomycin | SC-1605 | C66H77N9O24 |
| Vancomycin Impurity A | SC-1601 | C65H73Cl2N9O24 |
| Vancomycin Impurity D | SC-1604 | C59H62Cl2N8O22 |
| Vancomycin Impurity C | SC-1603 | C53H52Cl2N8O17 |
| Vancomycin Impurity B | SC-1602 | C66H74Cl2N8O25 |
| INO-4995 | INO-4995 | C50H86O35P4 |
| Fidaxomicin - d7 | SC-1157 | C52H67D7Cl2O18 |
| Podophyllotoxin Derivate | SC-0025 | C21H20O8 |
| Podophyllotoxin Derivate | SC-0026 | C21H21NO7 |
| Clopidogrel Impurity 4 | SC-0099 | C16H16ClNO2S * H2SO4 |
| Gestodene Impurity E | SC-0028 | C21H24O3 |
| Fidaxomicin Metabolite OP-1118 | SC-1158 | C48H68Cl2O17 |
| Prasugrel metabolite M6-d3 (stabilzed) | SC-0093 | C27H25D3FNO5S * HCl |
| Prasugrel metabolite M6 | SC-0092 | C19H22FNO3S |
| Clopidogrel Impurity C | SC-0087 | C16H18ClNO2S |
| Clopidogrel Impurity 3 | SC-0086 | C15H17Cl2NO2S |
| Prasugrel active metabolite M3-d3 (stabilzed) | SC-0033 | C27H25D3FNO5S * HCl |
| Prasugrel active metabolite M3 HCl (stabilized) | SC-0029 | C27H28FNO5S * HCl |
| Fidaxomicin - d7 | SC-1157 | C52H67D7Cl2O18 |
| Methyl 4-(2-hydroxyethyl)benzoate-13C6,2D (Ring-13C6,Ethyl-1,2-D2) | SC-0080 | C4 13C6 H10 D2 O3 |
| Anthracene 13C6 | SC-0074 | 13C6C8H8 |
| Phenanthrene 13C6 | SC-0073 | 13C6C8H8 |
| Naphthalene 13C10 | SC-0072 | 13C10H8 |
| Naphthalene 13C6 | SC-0071 | 13C6C4H8 |
| Prasugrel active metabolite M3-d3 (stabilzed) | SC-0033 | C27H25D3FNO5S * HCl |
| 2-Cyanoethyl N,N-diisopropylchlorophosphoramidite | SC-0091 | C9H18ClN2OP |
| Phosphoramidous acid. N.N-bis(1-methylethyl)-. bis(2-cyanoethyl) ester | SC-0061 | C12H22N3O2P |
| Phosphoramidous acid, N,N-bis(1-methylethyl)-, bis(phenylmethyl) ester | SC-1165 | C20 H28 N O2 P |
| Phosphorodiamidous acid. N.N.N'.N'-tetrakis(1-methylethyl)-. phenylmethyl ester | SC-0060 | C19 H35 N2 O P |
| Phosphoramidous acid. N.N-bis(1-methylethyl)-. 2-cyanoethyl [1-(2-nitrophenyl)ethyl] ester) | SC-0059 | C17 H26 N3 O4 P |
| Dichloro N,N-Diisopropylphosphoramidite | SC-0058 | C6 H14 Cl2 N P |
| Phosphoramidous acid. N.N-bis(1-methylethyl)-. bis(9H-fluoren-9-ylmethyl) ester | SC-0057 | C34 H36 N O2 P |
| Di-tert-butyl chloromethyl phosphate | SC-0011 | C9H20ClO4P |
| Di-benzyl chloromethyl phosphate | SC-0010 | C15H16ClO4P |
| TMe-OHB-DAZA | SC-0300 | C29H37N3O6 |
| TEt-OHB-DAZA | SC-0301 | C32H43N3O6 |
| NEmo2E | SC-0201 | C96H138KN18O30S |
| NEmo1 | SC-0200 | C96H138KN18O30S |
| D-Serine-O-phosphate | SC-1810 | C3H8NO6P |
| Ph-CCA-NH2 | SC-1400 | C16H12N2O |
| Menaquinone 8 / MK 8:8 | SC-1230 | C51H72O2 |
| Allyl-Maleimide | SC-1121 | C7H7NO2 |
| Nor-cisapride Derivative | SC-1161 | C17H25Cl2N3O3 |
| AlK - L - Lysine - HCl-salt | SC-8012 | C10H18N2O4* HCl |
| 4-methyl-2,2-bis(trifluoromethyl)oxazolidin-5-one | SC-0098 | C6H5F6NO2 |
| 3-(5-oxo-2,2-bis(trifluoromethyl)oxazolidin-4-yl)propanoic acid | SC-0097 | C8H7F6NO4 |
| 7-(diethylamino)-4-(hydroxymethyl)-coumarin / DEACM | SC-0096 | C14H17NO3 |
| 3-bromo-4-methyl-7-(diethylamino)-coumarin | SC-0095 | C14H16BrNO2 |
| Xanthohumol | SC-0094 | C21H22O5 |
| IEPOX 4 | SC-0090 | C5H10O3 |
| IEPOX 3 | SC-0089 | C5H10O3 |
| 2-C-Methyl-L-Threitol | SC-0085 | C5H12O4 |
| 2-C-Methyl-D-Threitol | SC-0084 | C5H12O4 |
| 2-C-Methyl-L-Erythritol | SC-0083 | C5H12O4 |
| 2-C-Methyl-D-Erythritol | SC-0082 | C5H12O4 |
| 3-Amino-7-(diethylamino)-coumarine | SC-0081 | C13 H16 N2 O2 |
| Chloromethylpropionate | SC-1164 | C4H7ClO2 |
| 2-(2-fluoro-2-methylpropoxy)-2-methylpropan-1-ol | SC-1163 | C8H17FO2 |
| 1,4-Di-butyryl-23:56-diisopropylidene-myo-Inositol | SC-0076 | C20H32O8 |
| 3,6-Di-butyryl-12:45-diisopropylidene-myo-Inositol | SC-0075 | C20H32O8 |
| Y-27632 | SC-0048 | C14H21N3O *2HCl |
| H-1152 | SC-0053 | C16H21N3O2S*2HCl |
| 3,4,5,6-Tetra-O-Benzyl-Ins | TOB-Ins-3456 | C34H36O6 |
| 1,4,5,6-Tetra-O-Benzyl-Ins | TOB-Ins-1456 | C34H36O6 |
| Biotin-PEG3-CoenzymeA | SC-8618 | C46H75N12O24P3S2+3NH3 |
| TMe-OHB-DAZA | SC-0300 | C29H37N3O6 |
| TEt-OHB-DAZA | SC-0301 | C32H43N3O6 |
| SCO-NHS carbonate | SC-8076 | C13H15NO5 |
| endo-BCN-NHS carbonate | SC-8074 | C15H17NO5 |
| TCO4 - NHS carbonate / EQUATORIAL isomer | SC-8073 | C13H17NO5 |
| TCO4 - NHS carbonate / AXIAL isomer | SC-8072 | C13H17NO5 |
| TCO* - NHS carbonate / EQUATORIAL isomer | SC-8071 | C13H17NO5 |
| TCO* - NHS carbonate / AXIAL isomer | SC-8070 | C13H17NO5 |
| NEmo2E | SC-0201 | C96H138KN18O30S |
| NEmo1 | SC-0200 | C96H138KN18O30S |
| bifunctional Cross-Linking-Amino-Acid / PrDiAzK | SC-8028 | C13H20N4O5 |
| Vancomycin hexapeptide | SC-1606 | C59H62Cl2N8O23 |
| Ph-CCA-NH2 | SC-1400 | C16H12N2O |
| Cross-Linking-Amino-Acid / DiAzK | SC-8034 | C11H20N4O4 |
| PEG-9 | SC-1509 | C18H38O10 |
| PEG-8 | SC-1508 | C16H34O9 |
| Click Amino Acid / cyclopropene – L - Lysine (CP) | SC-8017 | C12H20N2O4 |
<艾美捷科技代理Terracebiotech品牌全系列产品
Terracebiotech的专业技术源于加州大学旧金山分校医学中心的肺研究小组,该小组曾助力明确肺表面活性物质的特性,随后研发出其合成形式,用于治疗患有呼吸窘迫综合征的早产儿。凭借在肺细胞生物学领域超过 25 年的实践研究经验,Terracebiotech将其专业技术应用于推动医学研究的进一步创新,以改善人类健康。
Terracebiotech的抗体(在人体肺部中特异性靶向肺泡上皮1型或2型细胞)经验证,可高效、可靠地用于以下应用:免疫组织化学 (IHC);蛋白质印迹法 (Western Blotting);通过流式细胞分选技术 (FACS) 进行细胞分离;半定量斑点印迹 (Semi-Quantitative Dot Blots);磁性细胞分选 (Magnetic Cell Sorting);冷冻免疫电镜 (TEM Cryo-Immunohistochemistry)。

▍Terracebiotech产品列表
| 品名 | 货号 | Validated For | Production Host | Isotype | 规格 |
| Anti HT1-56 | TB-29AHT1-56 | IHC, Western Blots, FACS, magnetic Cell Sorting, Dot blots, and TEM | Mouse hybridoma cells | Mouse IgG1 | 1ml |
| Anti HT2-280 | TB-27AHT2-280 | IHC, Western Blots, FACS, magnetic Cell Sorting, Dot blots, and TEM | Mouse hybridoma cells | Mouse IgM | 1ml |
| Anti RT1-40 | TB-11ART1-40 | IHC, Western Blots, FACS, magnetic sell sorting, and dot blots. | Mouse hybridoma cells | Mouse IgG1 | 1ml |
| Anti RT2-70 | TB-44ART2-70 | IHC, FACS, magnetic Cell Sorting, and dot blots. | Mouse hybridoma cells | Mouse IgG3 | 1ml |

艾美捷科技代理LifeSensors品牌。
LifeSensors成立于1996年,位于美国宾夕法尼亚州费城,是一家为药物发现与研究提供方法和可行性技术方法的生物技术公司。公司致力于为泛素和泛素蛋白酶体通路研究领域提供高品质
的抗体、酶、蛋白质等试剂和试剂盒,产品,是泛素研究者的好选择。
其原核和真核蛋白表达系统SUMOpro和SUMOstar已被世界范围内的学术、政府研究机构和制药、生物技术公司广泛应用。通过提供创新的研究工具,LifeSensors已成为泛素和泛素样蛋
白途径的优质供应商。
LifeSensors公司目前主要的产品有400多种,其产品主要覆盖泛素和泛素蛋白酶体通路等科学应用领域,并且产品线在不断的扩大中。公司开创了两大独家技术平台:用于细胞信号和药物
发现的泛素蛋白酶体系统(UPS),以及增强目的蛋白在大肠杆菌、酵母、昆虫和哺乳动物细胞中表达与纯化的SUMO融合表达系统。泛素蛋白酶体系统正在成为继激酶之后,药物发现的下
一个机遇,必将成为未来许多新型药物的创新来源。作为泛素蛋白领域的先驱公司,药物的发现、分析化合物以及去泛素酶和泛素化酶的高通量筛选正是LifeSensors创新技术的真正亮点。
此外,LifeSensors还为泛素的蛋白质组学提供众多定制技术服务,并且已经开发了各种各样的测定细胞中的生理底物或生物标志物的方法。
< " data-original="http://bangs.51antibodies.com/template/company/xys_lvse/skin/image/lazyLoad.jpg" alt="艾美捷科技代理LifeSensors品牌"> 艾美捷科技代理LifeSensors品牌
<艾美捷科技代理Vectorbiolabs品牌全系列产品
Vector Biolabs是一家专注于提供高质量AAV(腺相关病毒)和腺病毒产品的生物科技公司,总部位于宾夕法尼亚州费城。Vector Biolabs公司提供包括定制病毒载体生产、载体设计、克隆、扩增、包装、纯化和滴度测定在内的服务,并且拥有一个包含超过90,000种针对人类、小鼠和大鼠基因组定制的AAV产品目录,服务于包括生物制药公司和研究机构在内的全球客户。此外,Vector Biolabs 为研究界提供与基因表达、基因编辑和基因沉默相关的服务。

▍Vectorbiolabs公司的产品与服务
● AAV定制生产:根据客户需求,定制生产AAV载体,以满足特定的研究或治疗需求。
● AAV控制产品:提供一系列用于AAV基因治疗的控制产品,确保实验的准确性和可靠性。
● 腺病毒建设与扩增:提供腺病毒的构建和扩增服务,支持客户的病毒载体研究。
● shRNA筛选/验证与产品目录:提供shRNA筛选和验证服务,以及相关的产品目录,帮助客户进行基因沉默研究。
使用AAV进行基因治疗的好处:
①低免疫反应:AAV载体引发免疫反应的可能性较低,适合敏感应用。
②稳定的基因递送:提供非整合基因递送,降低诱变风险。
③可扩展的生产:确保从小规模到大规模的研究和临床试验的可靠供应。
④广泛的治疗应用:多功能性使其成为靶向大脑、肝脏和视网膜等器官的理想选择。
| 特性 | AAV | 腺病毒 (Adenovirus) |
| 基因表达 | 长期、稳定表达 | 快速、瞬时表达 |
| 免疫原性 | 低 | 高 |
| 装载容量 | ~4.7 kb | ~8 kb - 38 kb (大得多) |
| 趋向性/靶向能力 | 高 - 可通过不同衣壳定制 | 广泛,可靶向多种组织 |
| 最佳应用场景 | 体内研究,长期表达 | 体外 & 体内研究,癌症 & 疫苗研究 |
▍Vectorbiolabs部分产品列表
| 品名 | 货号 | AAV Serotype | AAV ITR | Promoter | Reporter | Storage Buffer | Titer | Viral Backbone | Volume (µL) |
| AAV1-LacZ | 7001 | AAV1 | AAV2 | CMV (ubiquitous) | LacZ | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |
| AAV1-GFP | 7002 | AAV1 | AAV2 | CMV (ubiquitous) | eGFP | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |
| AAV2-LacZ | 7003 | AAV2 | AAV2 | CMV (ubiquitous) | LacZ | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |
| AAV2-GFP | 7004 | AAV2 | AAV2 | CMV (ubiquitous) | eGFP | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |
| AAV5-LacZ | 7005 | AAV5 | AAV2 | CMV (ubiquitous) | LacZ | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |
| AAV5-GFP | 7006 | AAV5 | AAV2 | CMV (ubiquitous) | eGFP | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |
| AAV9-GFP | 7007 | AAV9 | AAV2 | CMV (ubiquitous) | eGFP | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |
| AAV6-GFP | 7008 | AAV6 | AAV2 | CMV (ubiquitous) | eGFP | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |
| AAV1-Cre | 7010 | AAV1 | AAV2 | CMV (ubiquitous) | - | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |
| AAV2-Cre | 7011 | AAV2 | AAV2 | CMV (ubiquitous) | - | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |
| AAV5-Cre | 7012 | AAV5 | AAV2 | CMV (ubiquitous) | - | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |
| AAV6-Cre | 7013 | AAV6 | AAV2 | CMV (ubiquitous) | - | PBS/5% Glycerol | 1x10^13 GC/ml | Recombinant AAV | 20 |

艾美捷科技代理3Helix品牌胶原蛋白杂交肽(CHP)。
胶原蛋白是几乎存在于所有人体组织中,在支持细胞生长和组织形成方面发挥着重要作用。胶原蛋白受损预示着结缔组织的损伤,也是多种涉及炎症和异常组织重塑的疾病的征兆,例如癌症、
心肌梗塞、关节炎、骨质疏松症和纤维化。然而,用传统技术很难定位受损的胶原蛋白。因此,3Helix公司开发了一系列专利性的胶原蛋白杂交肽,可直接定位受损的胶原蛋白分子。
3Helix产品包括:
(1)Auto-CHP:胶原蛋白杂交肽,用于自动染色的生物素结合物;
(2)B-CHP:胶原蛋白杂交肽,生物素结合物;
(3)F-CHP:胶原蛋白杂交肽,5-FAM 结合物;
(4)In vivo:胶原蛋白杂交肽,磺基-Cy7.5 结合物 (sCy7.5-CHP);
(5)R-CHP:胶原蛋白杂交肽,Cy3 结合物。
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<艾美捷科技代理Protide Pharmaceuticals品牌全系列产品
Protide Pharmaceuticals, Inc.是一家专注于生物制药生产上游工艺的创新型公司。Protide Pharmaceuticals公司的核心产品为血清替代物,其核心价值在于提供高性能、化学成分明确、无动物来源的血清替代物和定制化培养基解决方案,帮助客户大幅减少生物制品生产过程中对胎牛血清或其他动物血清的依赖。,从而提高生物制品生产的效率、一致性、安全性和合规性。
除了血清替代物,Protide Pharmaceuticals公司也提供完整的、优化的无血清培养基配方,专门设计用于支持各种哺乳动物细胞系(如CHO, HEK293, Vero, MRC-5等)在生物反应器中进行高密度培养和高产率生产目标生物分子(如抗体、病毒载体、重组蛋白)。其产品应用于再生医学、肿瘤生物学、细胞生物能量学、肿瘤免疫学、转化医学、表观遗传学,胰岛细胞移植等领域。

▎Protide Pharmaceuticals产品线
● 血清替代品/生物制品生产培养基
Protide Pharmaceuticals的血清替代品通过提供优质、生物一致且功能性的环境,显著改善细胞的生理状态。所有血清替代品均配制成 50 倍浓缩液,这大大降低了成本,并改善了储存和供应链活动。Protide血清替代品不含:酚红、生长因子、类固醇激素、糖皮质激素、细胞粘附分子、生长因子、类固醇激素等物质,可以在其缺失或存在的情况下进行有效研究。细胞分泌的蛋白质可以在不受污染性血清成分干扰的情况下实现高度纯化。
| 品名 | 货号-规格 | 产品描述 |
| TCH™ | 3001-40ml;3002-100ml;3005-100ml | 本血清替代品主要用于人类细胞培养及细胞分泌蛋白的生产。TCH™ 在培养其他哺乳动物细胞时同样有效,且不含动物蛋白。其成分仅包含经热处理的人源蛋白(即人血清白蛋白、人转铁蛋白、重组人胰岛素)。 |
| VaxMax™ | 6004-100ml;6005-500ml;6006-1L | 100倍浓缩液是一种高性价比产品,可显著降低总体血清需求量。在MDBK、MDCK、Vero、CRFK及猪睾丸细胞培养中,使用VaxMax™已展现出显著的产量提升。兽用疫苗生产商已采用VaxMax™来增强生产,同时降低总体成本。VaxMax™通常与0.5%至1% 的血清配合使用。 |
| HemaPro™ | 3300-40ml;3303-100ml | 本产品为无血清添加剂,专为人祖细胞培养而设计。可有效用于癌症干细胞、诱导多能干细胞和间充质干细胞 的研究。不含:促红细胞生成素;重组生长因子。 |
| TM-235™ | 2001-40ml;2002-100ml;2005-500ml | 本血清替代品具有与TCM™类似的特性,但额外添加了适用于需要更高血清浓度(通常超过10%)的细胞类型的成分。TM-235™是一种成分明确且多用途的替代品。 |
| TCM™ | 1001-40ml;1002-100ml;1005-500ml | 本产品是一种通用型血清替代品,适用于多种物种来源的广泛细胞类型。TCM™是一种成分明确且多用途的血清替代品,可有效用于研究生长因子的影响以及蛋白质的生产。 |
● 低温保护剂
| 品名 | 货号-规格 | 产品描述 |
| Stemsol™ USP (DMSO) | PP1250-5ml;PP1300-10ml;PP1350-50ml;PP1400-100ml | 本产品为干细胞冻存溶液,适用于来源于脐带血、外周血、骨髓及其他生物组织和细胞的干细胞。 |
| pZerve™ | 5700-60ml;5720-20ml | pZerve™ 是一款独特的冻存溶液,不含 DMSO、胎牛血清或动物蛋白。本品为即用型,无需任何稀释或进一步处理。适用细胞类型包括:肥大细胞、树突细胞、间充质细胞、人转移性前列腺腺癌细胞、人结肠腺癌细胞,人转化胚肾细胞。 |
| Cellvation™ | 5001-60ml | Cellvation™ 是一款独特的冻存溶液,不含 DMSO 或胎牛血清。本品使用便捷,并能提供最佳的细胞复苏效果。在冷冻程序启动前,细胞可置于 Cellvation™ 中较长时间。本品为即用型,适用于无血清培养基或含血清培养基培养的细胞。 |
| MiCord™ 55% DMSO USP 5% Dextran USP | 1505-5ml;1500-7ml;;1700-10ml;1550-50ml;1600-100ml | 本产品为干细胞冻存溶液,适用于来源于脐带血、外周血、骨髓及其他生物组织和细胞的干细胞。 |
| 2-8CELLsius™ + DMSO,5% DMSO | PP338DM5-10ml;PP338DM5-100ml;PP338DM5-100B | 当与DMSO配合使用时,2-8CELLsius™可用作冻存液。2-8CELLsius™ + DMSO冻存液是一种细胞保护性、无蛋白溶液,含有生物稳定剂,可支持冻融后细胞的高存活率。其通过针对超低温下细胞生理学的创新方法,实现最佳的细胞复苏效果。不含:任何生长因子,激素以及抗生素。 |
| 2-8CELLsius™ + DMSO,10% DMSO | PP338DM10-10ml;PP338DM10-100ml;PP338DM10-100B;PP338DM10-1000B | |
| 2-8CELLsius™ + DMSO,20% DMSO | PP338DM20-100B;PP338DM20-1000B |
● 细胞处理
| 品名 | 货号-规格 | 产品描述 |
| 2-8CELLsius™ | PP338-100ml;PP338-500ml;PP338-1000;PP338-1000B | 即用型、平衡、细胞保护性、无蛋白溶液,含生物稳定剂,适用于:短期储存、再生医学、干细胞处理以及生物材料运输。 |
| Dextran 40 in 0.9% NaCl | PP1850-50ml;PP1840-1000ml;PP1880-250ml;PP1900-500ml | - |
| Dulbecco’s Phosphate Buffered Saline (10X) PBS | PBS210-500ml;PBS211-1000ml | 无钙镁储存条件:15-30°C;包装于PETG瓶;稳定性:至少6个月;无菌过滤 |
| Dulbecco’s Phosphate Buffered Saline (1X) PBS | PBS200-500ml;PBS201-1000ml | 无钙镁储存条件:15-30°C;包装于PETG瓶;稳定性:至少6个月;无菌过滤 |
| Hank’s Balanced Salt Solution (1X) HBSS | HS240-500ml;HS241-1000ml | 无钙镁配方:储存温度 4-8°C;无酚红配方;稳定性:至少6个月;含0.35克/升 碳酸氢钠;含1000毫克/升 D-葡萄糖;包装于 PETG 瓶,无菌过滤。cGMP 规范生产。 |
● CIT 胰岛细胞溶液
| 品名 | 货号-规格 |
| Cold Storage/Purification Stock Solution | 111098-1L |
| Phase I Solution | 060899-1L |
<艾美捷科技代理Research Products International(RPI)品牌全系列产品
Research Products International成立于1970年,总部位于伊利诺伊州展望山市 (Mount Prospect, Illinois),是化学品与生物化学品领域的领先制造商和供应商,并且获得ISO 9001:2008和GMP ISO 22716:2007认证。公司的五大主要产品线涵盖逾7,000种适用于植物与生命科学研究实验室的产品。除了自主生产的产品外,RPI还代理大多数领先品牌的科学设备。RPI公司的产品线包括抗生素、生物化学品、缓冲液、培养基以及实验室耗材。

▍Research Products International(RPI)部分产品列表
| 品名 | 货号 | CAS号 | 分子量 | 分子式 | Solubility | 储存温度 |
| 17-AAG | A20045 | 75747-14-7 | 585.7 | C31H43N3O8 | DMSO, Methanol | -20°C |
| Actinomycin D | A10025 | 50-76-0 | 1255.5 | C62H86N12O16 | DMSO, ethanol | 2-8°C |
| Allopurinol | A21000 | 315-30-0 | 136.11 | C5H4N4O | 1M NaOH | Room Temperature |
| Amdinocillin | A91690 | 32887-01-7 | 325.43 | C15H23N3O3S | - | 2-8°C |
| Amikacin | A20530 | 37517-28-5 | 585.6 | C22H43N5O13 | Water | 2-8°C |
| Amikacin Disulfate | A20540 | 39831-55-5 | 781.77 | C22H43N5O13 • 2H2SO4 | Water | 2-8°C |
| Amoxicillin Trihydrate | A40020 | 61336-70-7 | 419.5 | C16H19N3O5S • 3H2O | Water | 2-8°C |
| Amphotericin B | A40030 | 1397-89-3 | 924.1 | C47H73NO17 | DMSO | -20°C |
| Amphotericin B 250ug/ml Solution | A40035 | 1397-89-3 | 924.1 | C47H73NO17 | Water | -20°C |
| Ampicillin Trihydrate | A40050 | 7177-48-2 | 403.46 | C16H19N3O4S • 3H2O | 1M HCl | 2-8°C |
| Ampicillin, Sodium Salt | A40040 | 69-52-3 | 371.4 | C16H18N3O4SNa | Water | 2-8°C |
| Anisomycin from streptomyces griseolus | A50100 | 22862-76-6 | 265.3 | C14H19NO4 | Ethanol | 2-8°C |
| Apramycin Sulfate | A50020 | 65710-07-8 | 637.6 | C21H41N5O11 - H2SO4 | Water | 2-8°C |
| Bacitracin | B32000 | 1405-87-4 | 1422.69 | C66H103N17O16S | Water, Ethanol, and Methanol | 2-8°C |
| Bafilomycin B1 | B52100 | 88899-56-3 | 816 | C44H65NO13 | Methanol, Ethanol, DMF or DMSO | -20°C |
| Blasticidin S HCl Solution 10mg/ml | B12150 | 3513-03-9 | 458.9 | C17H26N8O5 • HCl | Water | -20°C |
| Blasticidin S Hydrochloride, Powder | B12200 | 3513-03-9 | 458.9 | C17H26N8O5 • HCl | Water | -20°C |
| 17-DMAG | D26100 | 467214-20-6 | 616.8 | C32H48N4O8 | DMSO, Ethanol | -20°C |
| Carbenicillin Disodium Salt | C46000 | 4800-94-6 | 422.4 | C17H16N2Na2O6S | Water | 2-8°C |
| Cefazolin Sodium Salt | C54500 | 27164-46-1 | 476.49 | C14H13N8NaO4S3 | Water | 2-8°C |
| Cefixime Trihydrate | C62720 | 125110-14-7 | 507.5 | C16H15N5O7S2 • 3H2O | - | Room Temperature |
| Cefoperazone Sodium Salt | C57600 | 62893-20-3 | 667.7 | C25H26N9NaO8S2 | Water | 2-8°C |
| Cefotaxime Sodium Salt | C51000 | 64485-93-4 | 477.5 | C16H16N5NaO7S2 | Water | 2-8°C |
| Cefsulodin Sodium Salt | C52000 | 52152-93-9 | 554.5 | C22H19N4NaO8S2 | Water | 2-8°C |
| Ceftazidime Hydrate | C59200 | 72558-82-8 | 546.5 | C22H22N6O7S2 • xH2O | Water | 2-8°C |
| Cefuroxime, Sodium Salt | C56300 | 56238-63-2 | 446.37 | C16H15N4NaO8S | DMSO, Methanol and Water | 2-8°C |
| Cephalexin Monohydrate | C59000 | 23325-78-2 | 365.4 | C16H17N3O4S-H2O | Water | 2-8°C |
| Cephalothin Sodium Salt | C59450 | 58-71-9 | 418.41 | C16H15N2NaO6S2 | Water | 2-8°C |
| Chlortetracycline Hydrochloride | C61040 | 64-72-2 | 515.3 | C22H23ClN2O8 • HCl | Water | -20°C |
| Clindamycin Hydrochloride | C41050 | 21462-39-5 | 461.5 | C18H33ClN2O5 • HCl | Water | 2-8°C |
| Cycloheximide | C81040 | 66-81-9 | 281.35 | C15H23NO4 | Ethanol, methanol | 2-8°C |
| D-Cycloserine | C81000 | 68-41-7 | 102.1 | C3H6N2O2 | Water | 2-8°C |
| Doxorubicin Hydrochloride | D43010 | 25316-40-9 | 580 | C27H29NO11 • HCl | Water | 2-8°C |
| Doxycycline Hydrochloride | D43020 | 10592-13-9 | 480.9 | C22H24N2O8 • HCl | Water | 2-8°C |
| Ertapenem Sodium Salt | E32100 | 153773-82-1 | 497.5 | C22H24N3NaO7S | Water | 2-8°C |
| Erythromycin | E57000 | 114-07-8 | 733.9 | C37H67NO13 | Ethanol | Room Temperature |

艾美捷科技代理Ocean Nanotech品牌纳米材料。
Ocean Nanotech, LLC专注于纳米材料、纳米技术及其生物医学应用。Ocean Nanotech公司技术特点在于:采用先进的合成技术,确保纳米材料的高纯度和高稳定性;多功能应用: 纳米材料具有广泛的应用前景,包括生物医学、光学、电子学等领域;定制化服务: 提供灵活的定制纳米材料设计和生产服务,满足客户需求。Ocean Nanotech公司纳米材料应用广泛,包括生物标记、细胞成像、药物传递和癌症治疗;光学传感器、光催化和光学成像;用于电子器件、传感器和导电材料;用于环境监测和污染治理。
Ocean Nanotech公司产品包括:
(1)纳米颗粒:提供多种纳米颗粒,包括金纳米颗粒、银纳米颗粒、量子点等,用于生物医学、光学和电子学应用。
(2)纳米材料试剂盒:提供用于生物标记、细胞成像和药物传递的纳米材料试剂盒。
(3)定制纳米材料:根据客户需求,提供定制化的纳米材料设计和生产服务。
(4)纳米技术咨询服务:提供纳米技术相关的咨询和技术支持服务。

艾美捷科技代理BioLab Assays 品牌。
BioLab Assays Ltd.开发、制造和销售创新和原创的即用ELISA(酶联免疫吸附测定)试剂盒。其产品组合包括固相96孔ELISA,设计用于定量测量细胞因子、急性反应物蛋白或趋化因子,并针对血清、血浆、尿液、唾液或脑脊液样品进行了优化。BioLab Assays公司产品涵盖以下领域:肥胖,IR,代谢综合征,糖尿病,肾脏疾病,肺部疾病,动物护理和研究,骨代谢,炎症和感染。
<BioLab Assays公司提供的产品和服务主要包括:
(1)即用型ELISA试剂盒:这是公司的核心产品,用于定量测量各种生物标志物,如细胞因子、急性反应物蛋白、趋化因子等。
(2)定制免疫检测开发:公司还提供定制免疫检测开发服务,以满足客户的特定需求。
(3)合同制造服务:除了自主开发和销售产品外,BioLab Assays公司还提供合同制造服务,为其他公司提供高质量的免疫检测产品。

艾美捷科技代理Dovetail Genomics品牌全系列产品
Dovetail Genomics公司成立于2013年,是染色体级别基因组组装领域的创新者,Dovetail Genomics公司正在解决包括染色质拓扑结构分析、大小体细胞变异检测、从头染色体组装和单倍型定相在内的复杂问题。Dovetail Genomics通过其专利的Hi-C/Omini-C技术,填补了短读长测序无法完成高质量组装的空白,产品广泛应用于表观遗传学、发育生物学、癌症研究、进化生物学、传染病等领域。

▍Dovetail Genomics公司的产品
| Dovetail Assay | ||||||
| Application | LinkPrep™ | Micro-C | HiChIP | Pan Promoter | Omni-C | |
| Genetic Variation | Large Structural Variant Detection Genotyping | √ | ||||
| Genotyping | √ | |||||
| Haplotype Phasing | √ | √ | ||||
| Chromatin Topology | Targeted Enhancer- Promoter Interactions | |||||
| Nucleosome-level Chromatin Topology | √ | |||||
| Whole Genome Rapid High-Resolution Topology | √ | |||||
| Protein Anchored Topology | √ | |||||
| Genetic Genome Assembly | Genome Scaffolding | √ | √ | |||
| Hybrid Capture Compatible | √ | √ | √ | |||
▍Dovetail® LinkPrep™ Kit
采用Tn5转座酶实现染色质均匀片段化,确保捕获无偏差的完整染色质三维构象。产品特点:
● 单日工作流:样本→测序文库仅需8小时(传统Hi-C需3-5天)
● 零专用设备:兼容常规分子生物学实验室
● 实现单倍型定相组装(Haplotype-resolved)
● 同步捕获全谱变异:SNV/InDel/CNV/SV(灵敏度达95%)
● 适用于基因组拓扑结构、遗传变异、基因组组装
▍Dovetail® Micro-C Kit
获取核小体分辨率的三维基因组图谱,针对需要单核小体级别精细拓扑图谱的研究(解析150-200 bp染色质构象),本技术可逐层解锁基因组三维结构。其在1千碱基对(kbp)以下分辨率呈现的高信噪比特性,使研究者能够以显著降低的成本构建高质量的染色质互作矩阵。产品特点:
● 核小体级精度:直接解析 150-200 bp染色质基本单元(单核小体)的空间构象,突破传统Hi-C技术分辨率限制(通常>1 kbp)
● 超高信噪比优势:在亚千碱基级别消除背景噪音,精确捕获微尺度拓扑关联域(如增强子-启动子互作)
● 成本降低:相较冷冻电镜或ChIA-PET等方法,实验成本下降60-80%; 矩阵数据质量提升(矩阵信噪比 > 95%,传统方法约70-85%)
▍Dovetail® Pan Promoter Kit
专为绘制“基因启动子-调控元件”三维互作图谱设计,通过靶向富集技术实现高分辨率、低成本的染色质构象分析。
▍Dovetail® HiChIP Kit
抗体导向的精准三维基因组捕获系统,融合Hi-C空间架构捕获与ChIP靶向富集技术,实现对特定蛋白(如CTCF、Cohesin、组蛋白修饰)介导的染色质互作进行纳米级分辨率解析。产品特点:
● 分辨率:200 bp(单核小体水平)
● 灵敏度:检测低频互作(≥5个细胞中1次事件)
● 特异性:抗体结合位点富集度 >100X;非特异性背景 <2%
● 样本兼容性:冰冻组织、FFPE样本、单细胞悬液
▍Dovetail® Omni-C® Kit
通过Tn5转座酶同时捕获染色质空间互作与酶切位点信息,核心优势:
● 高分辨率:精准解析拓扑关联结构域(TADs)、染色质环
● 多组学整合:单次实验同步检测染色质构象+基因变异(SNV/InDel/CNV/SV)
● 样本兼容性:支持微量样本(>50mg组织/ >10,000个细胞)
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