A ratiometric fluorescent probe for the detection of hypochlorous acid in living cells and zebra fish with a long wavelength emission
|
摘要
A ratiometric fluorescence probe, NClO, for the rapid and selective detection of HClO had been designed and synthesized based on a 1,8-naphthalimide derivative. Probe NClO displayed a red emission(λ_(max)= 615 nm). In the presence of HClO, the solution of probe NClO gave off a strong green fluorescence(λ_(em), _(max)= 520 nm) with a rapid response(within seconds). This probe had been applied to image HClO in living cells and zebra fish.
A ratiometric fluorescence probe, NClO, for the rapid and selective detection of HClO had been designed and synthesized based on a 1,8-naphthalimide derivative. Probe NClO displayed a red emission(λ_(max)= 615 nm). In the presence of HClO, the solution of probe NClO gave off a strong green fluorescence(λ_(em), _(max)= 520 nm) with a rapid response(within seconds). This probe had been applied to image HClO in living cells and zebra fish.
A ratiometric fluorescence probe, NClO, for the rapid and selective detection of HClO had been designed and synthesized based on a 1,8-naphthalimide derivative. Probe NClO displayed a red emission(λ_(max)= 615 nm). In the presence of HClO, the solution of probe NClO gave off a strong green fluorescence(λ_(em), _(max)= 520 nm) with a rapid response(within seconds). This probe had been applied to image HClO in living cells and zebra fish.
引文
[1]M.R.Detty,P.B.Merkel,R.Hilf,S.L.Gibson,S.K.Powers,J.Med.Chem.33(1990)1108-1116.
[2]D.I.Pattison,M.J.Davies,Chem.Res.Toxicol.14(2001)1453-1464.
[3]S.Drevet,G.Gavazzi,L.Grange,C.Dupuy,B.Lardy,Exp.Gerontol.111(2018)107-117.
[4]X.Chen,F.Wang,J.Y.Hyun,et al.,Chem.Soc.Rev.45(2016)2976-3016.
[5]X.Liu,Z.Tang,B.Song,H.Ma,J.Yuan,J.Mater.Chem.B 5(2017)2849-2855.
[6]H.Ma,B.Song,Y.Wang,et al.,Chem.Sci.8(2017)150-159.
[7]C.Yin,H.Zhu,C.Xie,et al.,Adv.Funct.Mater.27(2017)1700493.
[8]P.Nagy,K.Lemma,M.T.Ashby,J.Org.Chem.72(2007)8838-8846.
[9]L.Qiao,H.Nie,Y.Wu,et al.,J.Mater.Chem.B 5(2017)525-530.
[10]Q.Xu,C.H.Heo,G.Kim,et al.,Angew.Chem.Int.Ed.Engl.54(2015)4890-4894.
[11]Q.S.Lin,Y.L.Huang,X.X.Fan,et al.,Talanta 170(2017)496-501.
[12]M.Ren,J.Nie,B.Deng,et al.,N.J.Chem.41(2017)5259-5262.
[13]Q.Yuan,Z.M.Zhao,Y.R.Zhang,et al.,Sens.Actuators B-Chem.247(2017)736-741.
[14]Y.Dai,S.Cheng,Z.Wang,et al.,ACS Nano 12(2018)455-463.
[15]J.D.García-Espinoza,P.Mijaylova-Nacheva,M.Avilés-Flores,Chemosphere 192(2018)142-151.
[16]J.Kalmár,M.Szabó,N.Simic,I.Fábián,Dalton Trans.47(2018)3831-3840.
[17]R.Zhang,B.Song,J.Yuan,Tr AC-Trends Anal.Chem.99(2018)1-33.
[18]B.Zhu,Y.Xu,W.Liu,et al.,Sens.Actuators B-Chem.191(2014)473-478.
[19]B.Zhang,X.Yang,R.Zhang,et al.,Anal.Chem.89(2017)10384-10390.
[20]P.Ning,W.Wang,M.Chen,Y.Feng,X.Meng,Chin.Chem.Lett.28(2017)1943-1951.
[21]Y.Chen,T.Wei,Z.Zhang,et al.,Chin.Chem.Lett.28(2017)1957-1960.
[22]J.Li,X.Yang,D.Zhang,et al.,Sens.Actuators B-Chem.265(2018)84-90.
[23]S.J.Li,D.Y.Zhou,Y.F.Li,et al.,Talanta 188(2018)691-700.
[24]H.Tong,Y.Zhang,S.Ma,et al.,Chin.Chem.Lett.29(2018)139-142.
[25]B.Zhu,L.Wu,M.Zhang,et al.,Biosens.Bioelectron.107(2018)218-223.
[26]Y.Gao,Y.Pan,Y.He,H.Chen,V.N.Nemykin,Sens.Actuators B-Chem.269(2018)151-157.
[27]X.Zhang,B.Wang,Y.Xiao,C.Wang,L.He,Analyst 143(2018)4180-4188.
[28]F.Yang,C.Wang,L.Wang,et al.,Chin.Chem.Lett.28(2017)2019-2022.
[29]H.Bian,X.Song,N.Li,H.Man,Y.Xiao,J.Mater.Chem.B 6(2018)1699-1705.
[30]C.Wang,X.Song,Y.Xiao,ChemBioChem 18(2017)1762-1769.
[31]Y.Dai,B.K.Lv,X.F.Zhang,Y.Xiao,Chin.Chem.Lett.25(2014)1001-1005.
[32]M.B.Iversen,R.H.Gottfredsen,U.G.Larsen,et al.,Free Radic.Biol.Med.97(2016)478-488.
[2]D.I.Pattison,M.J.Davies,Chem.Res.Toxicol.14(2001)1453-1464.
[3]S.Drevet,G.Gavazzi,L.Grange,C.Dupuy,B.Lardy,Exp.Gerontol.111(2018)107-117.
[4]X.Chen,F.Wang,J.Y.Hyun,et al.,Chem.Soc.Rev.45(2016)2976-3016.
[5]X.Liu,Z.Tang,B.Song,H.Ma,J.Yuan,J.Mater.Chem.B 5(2017)2849-2855.
[6]H.Ma,B.Song,Y.Wang,et al.,Chem.Sci.8(2017)150-159.
[7]C.Yin,H.Zhu,C.Xie,et al.,Adv.Funct.Mater.27(2017)1700493.
[8]P.Nagy,K.Lemma,M.T.Ashby,J.Org.Chem.72(2007)8838-8846.
[9]L.Qiao,H.Nie,Y.Wu,et al.,J.Mater.Chem.B 5(2017)525-530.
[10]Q.Xu,C.H.Heo,G.Kim,et al.,Angew.Chem.Int.Ed.Engl.54(2015)4890-4894.
[11]Q.S.Lin,Y.L.Huang,X.X.Fan,et al.,Talanta 170(2017)496-501.
[12]M.Ren,J.Nie,B.Deng,et al.,N.J.Chem.41(2017)5259-5262.
[13]Q.Yuan,Z.M.Zhao,Y.R.Zhang,et al.,Sens.Actuators B-Chem.247(2017)736-741.
[14]Y.Dai,S.Cheng,Z.Wang,et al.,ACS Nano 12(2018)455-463.
[15]J.D.García-Espinoza,P.Mijaylova-Nacheva,M.Avilés-Flores,Chemosphere 192(2018)142-151.
[16]J.Kalmár,M.Szabó,N.Simic,I.Fábián,Dalton Trans.47(2018)3831-3840.
[17]R.Zhang,B.Song,J.Yuan,Tr AC-Trends Anal.Chem.99(2018)1-33.
[18]B.Zhu,Y.Xu,W.Liu,et al.,Sens.Actuators B-Chem.191(2014)473-478.
[19]B.Zhang,X.Yang,R.Zhang,et al.,Anal.Chem.89(2017)10384-10390.
[20]P.Ning,W.Wang,M.Chen,Y.Feng,X.Meng,Chin.Chem.Lett.28(2017)1943-1951.
[21]Y.Chen,T.Wei,Z.Zhang,et al.,Chin.Chem.Lett.28(2017)1957-1960.
[22]J.Li,X.Yang,D.Zhang,et al.,Sens.Actuators B-Chem.265(2018)84-90.
[23]S.J.Li,D.Y.Zhou,Y.F.Li,et al.,Talanta 188(2018)691-700.
[24]H.Tong,Y.Zhang,S.Ma,et al.,Chin.Chem.Lett.29(2018)139-142.
[25]B.Zhu,L.Wu,M.Zhang,et al.,Biosens.Bioelectron.107(2018)218-223.
[26]Y.Gao,Y.Pan,Y.He,H.Chen,V.N.Nemykin,Sens.Actuators B-Chem.269(2018)151-157.
[27]X.Zhang,B.Wang,Y.Xiao,C.Wang,L.He,Analyst 143(2018)4180-4188.
[28]F.Yang,C.Wang,L.Wang,et al.,Chin.Chem.Lett.28(2017)2019-2022.
[29]H.Bian,X.Song,N.Li,H.Man,Y.Xiao,J.Mater.Chem.B 6(2018)1699-1705.
[30]C.Wang,X.Song,Y.Xiao,ChemBioChem 18(2017)1762-1769.
[31]Y.Dai,B.K.Lv,X.F.Zhang,Y.Xiao,Chin.Chem.Lett.25(2014)1001-1005.
[32]M.B.Iversen,R.H.Gottfredsen,U.G.Larsen,et al.,Free Radic.Biol.Med.97(2016)478-488.