Lumiprobe公司简介

Lumiprobe Corporation是美国一家高品质生物技术公司，专业提供分子生物学研究用的活性荧光染料。从2006年开始，我公司生产并销售生命科学研究和诊断学应用的优质化学药品。我们的产品主要有：活性染料(Reactive Dye)和SYBR Green I 染料，用于寡核苷酸合成的亚磷酰胺，点击化学和其它试剂。大部分产品我们都有库存，可以随时发到世界各个地方。

产品主要应用：点击化学(Click Chemistry)、蛋白质组学研究中的双向荧光差异凝胶电泳(2D DIGE)和实时荧光定量PCR(Realtime PCR)。

产品

Lumiprobe 产品列表
货号	产品名称	货号	产品名称
21360	Alkyne Amidite, hydroxyprolinol, 250 mg	65090	Cy7 carboxylic acid, 100 mg
41360	Alkyne Amidite, hydroxyprolinol, 1 g	15080	Cy7 maleimide, 1 mg
22260	Alkyne Phosphoramidite, 5'-terminal, 250 mg	25080	Cy7 maleimide, 5 mg
42260	Alkyne Phosphoramidite, 5'-terminal, 1 g	45080	Cy7 maleimide, 25 mg
62260	Alkyne Phosphoramidite, 5'-terminal, 5 g	55080	Cy7 maleimide, 50 mg
15040	Amino-11-ddUTP, 1 umol	65080	Cy7 maleimide, 100 mg
25040	Amino-11-ddUTP, 5 umol	15020	Cy7 NHS ester, 1 mg
45040	Amino-11-ddUTP, 25 umol	25020	Cy7 NHS ester, 5 mg
16040	Amino-11-dUTP, 1 umol	45020	Cy7 NHS ester, 25 mg
26040	Amino-11-dUTP, 5 umol	55020	Cy7 NHS ester, 50 mg
46040	Amino-11-dUTP, 25 umol	65020	Cy7 NHS ester, 100 mg
12050	Ascorbic acid, 10 mg	16030	Cy7.5 azide, 100 uL, 10 mM in DMS
33720	Azidobutyric acid NHS ester, 10 mg	36030	Cy7.5 azide, 500 uL, 10 mM in DMS
43720	Azidobutyric acid NHS ester, 25 mg	46030	Cy7.5 azide, 1 mL, 10 mM in DMSO
53720	Azidobutyric acid NHS ester, 50 mg	A6030	Cy7.5 azide, 1 mg
21050	Copper(II)-TBTA complex, 10 mM in 55% aq. DMSO, 1.5 mL	B6030	Cy7.5 azide, 5 mg
A1430	Coumarin 343 azide, 1 mg	C6030	Cy7.5 azide, 10 mg
B1430	Coumarin 343 azide, 5 mg	D6030	Cy7.5 azide, 25 mg
C1430	Coumarin 343 azide, 10 mg	E6030	Cy7.5 azide, 50 mg
D1430	Coumarin 343 azide, 25 mg	16090	Cy7.5 carboxylic acid, 1 mg
E1430	Coumarin 343 azide, 50 mg	26090	Cy7.5 carboxylic acid, 5 mg
1A041	Cy2 NHS ester for 2D electrophoresis, 5 nmol	46090	Cy7.5 carboxylic acid, 25 mg
2A041	Cy2 NHS ester for 2D electrophoresis, 10 nmol	56090	Cy7.5 carboxylic acid, 50 mg
3A041	Cy2 NHS ester for 2D electrophoresis, 25 nmol	66090	Cy7.5 carboxylic acid, 100 mg
A10B0	Cy3 alkyne, 1 mg	16080	Cy7.5 maleimide, 1 mg
B10B0	Cy3 alkyne, 5 mg	26080	Cy7.5 maleimide, 5 mg
C10B0	Cy3 alkyne, 10 mg	46080	Cy7.5 maleimide, 25 mg
D10B0	Cy3 alkyne, 25 mg	56080	Cy7.5 maleimide, 50 mg
E10B0	Cy3 alkyne, 50 mg	66080	Cy7.5 maleimide, 100 mg
11030	Cy3 azide, 100 uL, 10 mM/DMSO	16020	Cy7.5 NHS ester, 1 mg
31030	Cy3 azide, 500 uL, 10 mM/DMSO	26020	Cy7.5 NHS ester, 5 mg
41030	Cy3 azide, 1 mL, 10 mM/DMSO	46020	Cy7.5 NHS ester, 25 mg
A1030	Cy3 azide, 1 mg	56020	Cy7.5 NHS ester, 50 mg
B1030	Cy3 azide, 5 mg	66020	Cy7.5 NHS ester, 100 mg
C1030	Cy3 azide, 10 mg	13050	DMF (dimethylformamide), labeling grade, 1 mL
D1030	Cy3 azide, 25 mg	23260	DMS(O)MT aminolink C6, 250 mg
E1030	Cy3 azide, 50 mg	43260	DMS(O)MT aminolink C6, 1 g
11090	Cy3 carboxylic acid, 1 mg	63260	DMS(O)MT aminolink C6, 5 g
21090	Cy3 carboxylic acid, 5 mg	14130	FAM azide, 5- isomer, 100 uL, 10 mM/DMSO
41090	Cy3 carboxylic acid, 25 mg	34130	FAM azide, 5- isomer, 500 uL, 10 mM/DMSO
51090	Cy3 carboxylic acid, 50 mg	44130	FAM azide, 5- isomer, 1 mL, 10 mM/DMSO
61090	Cy3 carboxylic acid, 100 mg	A4130	FAM azide, 5- isomer, 1 mg
11080	Cy3 maleimide, 1 mg	B4130	FAM azide, 5- isomer, 5 mg
21080	Cy3 maleimide, 5 mg	C4130	FAM azide, 5- isomer, 10 mg
41080	Cy3 maleimide, 25 mg	D4130	FAM azide, 5- isomer, 25 mg
51080	Cy3 maleimide, 50 mg	E4130	FAM azide, 5- isomer, 50 mg
61080	Cy3 maleimide, 100 mg	15130	FAM azide, 6- isomer, 100 uL, 10 mM/DMSO
11020	Cy3 NHS ester, 1 mg	35130	FAM azide, 6- isomer, 500 uL, 10 mM/DMSO
21020	Cy3 NHS ester, 5 mg	45130	FAM azide, 6- isomer, 1 mL, 10 mM/DMSO
41020	Cy3 NHS ester, 25 mg	A5130	FAM azide, 6- isomer, 1 mg
51020	Cy3 NHS ester, 50 mg	B5130	FAM azide, 6- isomer, 5 mg
61020	Cy3 NHS ester, 100 mg	C5130	FAM azide, 6- isomer, 10 mg
1B041	Cy3 NHS ester for 2D electrophoresis, 5 nmol	D5130	FAM azide, 6- isomer, 25 mg
2B041	Cy3 NHS ester for 2D electrophoresis, 10 nmol	E5130	FAM azide, 6- isomer, 50 mg
3B041	Cy3 NHS ester for 2D electrophoresis, 25 nmol	24260	Long trebler phosphoramidite, 250 mg
12030	Cy3.5 azide, 100 uL, 10 mM/DMSO	34260	Long trebler phosphoramidite, 500 mg
32030	Cy3.5 azide, 500 uL, 10 mM/DMSO	44260	Long trebler phosphoramidite, 1 g
42030	Cy3.5 azide, 1 mL, 10 mM/DMSO	30720	Pentynoic acid STP ester, 10 mg
A2030	Cy3.5 azide, 1 mg	40720	Pentynoic acid STP ester, 25 mg
B2030	Cy3.5 azide, 5 mg	50720	Pentynoic acid STP ester, 50 mg
C2030	Cy3.5 azide, 10 mg	60720	Pentynoic acid STP ester, 100 mg
D2030	Cy3.5 azide, 25 mg	A4530	PEP azide, 1 mg
E2030	Cy3.5 azide, 50 mg	B4530	PEP azide, 5 mg
12020	Cy3.5 NHS ester, 1 mg	C4530	PEP azide, 10 mg
22020	Cy3.5 NHS ester, 5 mg	D4530	PEP azide, 25 mg
42020	Cy3.5 NHS ester, 25 mg	E4530	PEP azide, 50 mg
52020	Cy3.5 NHS ester, 50 mg	A5530	Perylene azide, 1 mg
62020	Cy3.5 NHS ester, 100 mg	B5530	Perylene azide, 5 mg
A30B0	Cy5 alkyne, 1 mg	C5530	Perylene azide, 10 mg
B30B0	Cy5 alkyne, 5 mg	D5530	Perylene azide, 25 mg
C30B0	Cy5 alkyne, 10 mg	E5530	Perylene azide, 50 mg
D30B0	Cy5 alkyne, 25 mg	A1530	Pyrene azide 1, 1 mg
E30B0	Cy5 alkyne, 50 mg	B1530	Pyrene azide 1, 5 mg
130C0	Cy5 amine, 1 mg	C1530	Pyrene azide 1, 10 mg
230C0	Cy5 amine, 5 mg	D1530	Pyrene azide 1, 25 mg
430C0	Cy5 amine, 25 mg	E1530	Pyrene azide 1, 50 mg
530C0	Cy5 amine, 50 mg	A2530	Pyrene azide 2, 1 mg
630C0	Cy5 amine, 100 mg	B2530	Pyrene azide 2, 5 mg
13030	Cy5 azide, 100 uL, 10 mM/DMSO	C2530	Pyrene azide 2, 10 mg
33030	Cy5 azide, 500 uL, 10 mM/DMSO	D2530	Pyrene azide 2, 25 mg
43030	Cy5 azide, 1 mL, 10 mM/DMSO	E2530	Pyrene azide 2, 50 mg
A3030	Cy5 azide, 1 mg	A3530	Pyrene azide 3, 1 mg
B3030	Cy5 azide, 5 mg	B3530	Pyrene azide 3, 5 mg
C3030	Cy5 azide, 10 mg	C3530	Pyrene azide 3, 10 mg
D3030	Cy5 azide, 25 mg	D3530	Pyrene azide 3, 25 mg
E3030	Cy5 azide, 50 mg	E3530	Pyrene azide 3, 50 mg
130A0	Cy5 Boc-hydrazide, 1 mg	11460	Pyrene phosphoramidite dU, 100 mg
230A0	Cy5 Boc-hydrazide, 5 mg	21460	Pyrene phosphoramidite dU, 250 mg
430A0	Cy5 Boc-hydrazide, 25 mg	41460	Pyrene phosphoramidite dU, 1 g
530A0	Cy5 Boc-hydrazide, 50 mg	14230	R110 azide, 5- isomer, 100 uL, 10 mM/DMSO
630A0	Cy5 Boc-hydrazide, 100 mg	34230	R110 azide, 5- isomer, 500 uL, 10 mM/DMSO
13090	Cy5 carboxylic acid, 1 mg	44230	R110 azide, 5- isomer, 1 mL, 10 mM/DMSO
23090	Cy5 carboxylic acid, 5 mg	15230	R110 azide, 6- isomer, 100 uL, 10 mM/DMSO
43090	Cy5 carboxylic acid, 25 mg	35230	R110 azide, 6- isomer, 500 uL, 10 mM/DMSO
53090	Cy5 carboxylic acid, 50 mg	45230	R110 azide, 6- isomer, 1 mL, 10 mM/DMSO
63090	Cy5 carboxylic acid, 100 mg	11230	ROX azide, 5- isomer, 100 uL, 10 mM/DMSO
13070	Cy5 hydrazide, 1 mg	31230	ROX azide, 5- isomer, 500 uL, 10 mM/DMSO
23070	Cy5 hydrazide, 5 mg	41230	ROX azide, 5- isomer, 1 mL, 10 mM/DMSO
43070	Cy5 hydrazide, 25 mg	A1230	ROX azide, 5- isomer, 1 mg
53070	Cy5 hydrazide, 50 mg	B1230	ROX azide, 5- isomer, 5 mg
63070	Cy5 hydrazide, 100 mg	C1230	ROX azide, 5- isomer, 10 mg
13080	Cy5 maleimide, 1 mg	D1230	ROX azide, 5- isomer, 25 mg
23080	Cy5 maleimide, 5 mg	E1230	ROX azide, 5- isomer, 50 mg
43080	Cy5 maleimide, 25 mg	12220	ROX NHS ester, pure 6- isomer, 1 mg
53080	Cy5 maleimide, 50 mg	22220	ROX NHS ester, pure 6- isomer, 5 mg
63080	Cy5 maleimide, 100 mg	42220	ROX NHS ester, pure 6- isomer, 25 mg
13020	Cy5 NHS ester, 1 mg	52220	ROX NHS ester, pure 6- isomer, 50 mg
23020	Cy5 NHS ester, 5 mg	62220	ROX NHS ester, pure 6- isomer, 100 mg
43020	Cy5 NHS ester, 25 mg	A1330	Sulfo-Cy3 azide, 1 mg
53020	Cy5 NHS ester, 50 mg	B1330	Sulfo-Cy3 azide, 5 mg
63020	Cy5 NHS ester, 100 mg	C1330	Sulfo-Cy3 azide, 10 mg
1C041	Cy5 NHS ester for 2D electrophoresis, 5 nmol	D1330	Sulfo-Cy3 azide, 25 mg
2C041	Cy5 NHS ester for 2D electrophoresis, 10 nmol	11320	Sulfo-Cy3 NHS ester, 1 mg
3C041	Cy5 NHS ester for 2D electrophoresis, 25 nmol	21320	Sulfo-Cy3 NHS ester, 5 mg
14030	Cy5.5 azide, 100 uL, 10 mM/DMSO	41320	Sulfo-Cy3 NHS ester, 25 mg
34030	Cy5.5 azide, 500 uL, 10 mM/DMSO	51320	Sulfo-Cy3 NHS ester, 50 mg
44030	Cy5.5 azide, 1 mL, 10 mM/DMSO	61320	Sulfo-Cy3 NHS ester, 100 mg
A4030	Cy5.5 azide, 1 mg	A3330	Sulfo-Cy5 azide, 1 mg
B4030	Cy5.5 azide, 5 mg	B3330	Sulfo-Cy5 azide, 5 mg
C4030	Cy5.5 azide, 10 mg	C3330	Sulfo-Cy5 azide, 10 mg
D4030	Cy5.5 azide, 25 mg	D3330	Sulfo-Cy5 azide, 25 mg
E4030	Cy5.5 azide, 50 mg	13390	Sulfo-Cy5 carboxylic acid, 1 mg
17090	Cy5.5 carboxylic acid, 1 mg	23390	Sulfo-Cy5 carboxylic acid, 5 mg
27090	Cy5.5 carboxylic acid, 5 mg	43390	Sulfo-Cy5 carboxylic acid, 25 mg
47090	Cy5.5 carboxylic acid, 25 mg	53390	Sulfo-Cy5 carboxylic acid, 50 mg
57090	Cy5.5 carboxylic acid, 50 mg	63390	Sulfo-Cy5 carboxylic acid, 100 mg
67090	Cy5.5 carboxylic acid, 100 mg	13320	Sulfo-Cy5 NHS ester, 1 mg
17080	Cy5.5 maleimide, 1 mg	23320	Sulfo-Cy5 NHS ester, 5 mg
27080	Cy5.5 maleimide, 5 mg	43320	Sulfo-Cy5 NHS ester, 25 mg
47080	Cy5.5 maleimide, 25 mg	53320	Sulfo-Cy5 NHS ester, 50 mg
57080	Cy5.5 maleimide, 50 mg	63320	Sulfo-Cy5 NHS ester, 100 mg
67080	Cy5.5 maleimide, 100 mg	15320	Sulfo-Cy7 NHS ester, 1 mg
17020	Cy5.5 NHS ester, 1 mg	25320	Sulfo-Cy7 NHS ester, 5 mg
27020	Cy5.5 NHS ester, 5 mg	45320	Sulfo-Cy7 NHS ester, 25 mg
47020	Cy5.5 NHS ester, 25 mg	55320	Sulfo-Cy7 NHS ester, 50 mg
57020	Cy5.5 NHS ester, 50 mg	65320	Sulfo-Cy7 NHS ester, 100 mg
67020	Cy5.5 NHS ester, 100 mg	41010	SYBR Green I for Real Time PCR, 100x, 1 mL
15030	Cy7 azide, 100 uL, 10 mM/DMSO	51010	SYBR Green I for Real Time PCR, 100x, 1.5 mL
35030	Cy7 azide, 500 uL, 10 mM/DMSO	51010-5	SYBR Green I for Real Time PCR, 100x, 5x1.5 mL
45030	Cy7 azide, 1 mL, 10 mM/DMSO	20010	SYBR Green I Gel Staining Solution, 10000x, 1 mL
A5030	Cy7 azide, 1 mg	17130	TAMRA azide, 5- isomer, 100 uL, 10 mM/DMSO
B5030	Cy7 azide, 5 mg	37130	TAMRA azide, 5- isomer, 500 uL, 10 mM/DMSO
C5030	Cy7 azide, 10 mg	47130	TAMRA azide, 5- isomer, 1 mL, 10 mM/DMSO
D5030	Cy7 azide, 25 mg	A7130	TAMRA azide, 5- isomer, 1 mg
E5030	Cy7 azide, 50 mg	B7130	TAMRA azide, 5- isomer, 5 mg
15090	Cy7 carboxylic acid, 1 mg	C7130	TAMRA azide, 5- isomer, 10 mg
25090	Cy7 carboxylic acid, 5 mg	D7130	TAMRA azide, 5- isomer, 25 mg
45090	Cy7 carboxylic acid, 25 mg	E7130	TAMRA azide, 5- isomer, 50 mg
55090	Cy7 carboxylic acid, 50 mg

参考文献：

2013

1. Sellrie, F.; Graser, E.; Lenz, C.; Hillebrand, T.; Schenk, J.A. Specific DNA detection using antibody mediated fluorescence quenching. Biosensors and Bioelectronics, 2013, 42, 512-515. doi:10.1016/j.bios.2012.10.055

2. Potapova, I.; Eglin, D.; Laschke, M.W.; Bischoff, M.; Richards, R.G.; Moriarty, T.F. Two-step labeling of Staphylococcus aureus with Lysostaphin-Azide and DIBO-Alexa using click chemistry. J. Microbiol. Methods, 2013, 92(1), 90–98. doi: 10.1016/j.mimet.2012.11.004

3. Gluz, E.; Mizrahi, D.M.; Margel, S. Synthesis and characterization of new poly(ethylene glycol)bisphosphonate vinylic monomer and non-fluorescent and NIR-fluorescent bisphosphonate micrometer-sized particles. Polymer, 2013, 54(2), 565-571. doi: 10.1016/j.polymer.2012.11.071

4. Kim, J.; Seo, M.-H.; Lee, S.; Cho, K.; Yang, A.; Woo, K.; Kim, H.-S.; Park, H.-S. Simple and Efficient Strategy for Site-Specific Dual Labeling of Proteins for Single-Molecule Fluorescence Resonance Energy Transfer Analysis. Anal. Chem., 2013, 85(3), 1468–1474. doi: 10.1021/ac303089v

5. Cao, Zh.; Partyka, K.; McDonald, M.; Brouhard, E.; Hincapie, M.; Brand, R.E.; Hancock, W.S.; Haab, B.B. Modulation of Glycan Detection on Specific Glycoproteins by Lectin Multimerization. Anal. Chem., 2013, 85(3), 1689-1698. doi: 10.1021/ac302826a

6. Astakhova, I.K.; Santhosh Kumar, T.; Campbell, M.A.; Ustinov, A.V.; Korshun, V.A.; Wengel, J. Branched DNA nanostructures efficiently stabilised and monitored by novel pyrene-perylene 2’-.alpha.-l-amino-LNA FRET pairs. Chem Commun., 2013, 49(5), 511-513. doi: 10.1039/c2cc37547h

2012

1. Truong, F.; Yoo, T.H.; Lampo, T.J.; Tirrell, D.A. Two-Strain, Cell-Selective Protein Labeling in Mixed Bacterial Cultures. J. Am. Chem. Soc., 2012, 134(20), 8551–8556. doi: 10.1021/ja3004667

2. Pecqueur, L.; Duellberg, C.; Dreier, B.; Jiang, Q.; Wang, C.; Pluckthun, A.; Surrey, T.; Gigant, B.; Knossow, M. A designed ankyrin repeat protein selected to bind to tubulin caps the microtubule plus end. Proc. Natl. Acad. Sci. USA, 2012, 109(30), 12011-12016. doi: 10.1073/pnas.1204129109

3. McGouran, J.F.; Kramer, H.B.; Mackeen, M.M; di Gleria, K.; Altun, M.; Kessler, B.M. Fluorescence-based active site probes for profiling deubiquitinating enzymes. Org. Biomol. Chem., 2012, 10, 3379-3383. doi:10.1039/C2OB25258A

4. Fan, H.; Zhang, I.Y.; Chen, X.; Zhang, L.; Wang, H.; da Fonseca, A.C.C.; Manuel, E.R.; Diamond, D.J.; Raubitschek, A.A.; Badie, B. Intracerebral CpG Immunotherapy with Carbon Nanotubes Abrogates Growth of Subcutaneous Melanomas in Mice. Clin. Cancer Res., 2012, 18(20), 5628-5638. doi:10.1158/1078-0432.CCR-12-1911

5. Sparks, J.; Slobodkin, G.; Matar, M.; Congo, R.; Ulkoski, D.; Rea-Ramsey, A.; Pence, C.; Rice, J.; McClure, D.; Polach, K.J.; Brunhoeber, E.; Wilkinson, L.; Wallace, K.; Anwer, K.; Fewell, J.G. Versatile cationic lipids for siRNA delivery. J. Controlled Release, 2012, 158(2), 269–276. doi: 10.1016/j.jconrel.2011.11.006

6. Meimetis, L.G.; Williams, D.E.; Mawji, N.R.; Banuelos, C.A.; Lal, A.A.; Park, J.J.; Tien, A.H.; Fernandez, J.G.; de Voogd, N.J.; Sadar, M.D.; Andersen, R.J. Niphatenones, glycerol ethers from the sponge Niphates digitalis block androgen receptor transcriptional activity in prostate cancer cells: structure elucidation, synthesis, and biological activity. J. Med. Chem., 2012, 55(1), 503-14. doi: 10.1021/jm2014056

7. Kim, W.-J.; Kim, A.; Huh, C.; Park, C.W.; Ah, C.S.; Kim, B.K.; Yang, J.-H.; Chung, K.H.; Choi, Y.H.; Hong, J.; Sung, G.Y. Photo selective protein immobilization using bovine serum albumin. Appl. Surface Sci., 2012, 261, 880–889. doi: 10.1016/j.apsusc.2012.08.111

8. Preus, S.; Wilhelmsson, M. Advances in Quantitative FRET-Based Methods for Studying Nucleic Acids.ChemBioChem, 2012, 13 (14), 1990-2001. doi: 10.1002/cbic.201200400

9. Kim, J.-y.; Shim, G. Choi, H.-w.; Park, J.; Chung, S.W.; Kim, S.; Kim, K.; Kwon, I.C.; Kim, C.-W.; Kim, S.Y.; Yang, V.C.; Oh, Y.-K.; Byun, Y. Tumor vasculature targeting following co-delivery of heparin-taurocholate conjugate and suberoylanilide hydroxamic acid using cationic nanolipoplex. Biomaterials, 2012, 33(17), 4424-4430. doi: 10.1016/j.biomaterials.2012.02.066

10. Adulnirath, A.; Chung, S.W.; Park, J.; Hwang, S.R.; Kim, J.-Y.; Yang, V.C.; Kim, S.Y.; Moon, H.T.; Byun, Y. Cyclic RGDyk-conjugated LMWH-taurocholate derivative as a targeting angiogenesis inhibitor. J. Controlled Release, 2012, 164(1), 8–16. doi:10.1016/j.jconrel.2012.10.001

11. Kovacic, S.; Samii, L.; Woolfson,D.N.; Curmi, P.M.G.; Linke, H.; Forde, N.R.; Blab, G.A. Design and Construction of a One-Dimensional DNA Track for an Artificial Molecular Motor. J. Nanomaterials, 2012. doi:10.1155/2012/109238

12. Molinari, C.E.; Casadio, Y.S.; Hartmann, B.T.; Livk, A.; Bringans, S.; Arthur, P.G.; Hartmann, P.E. Proteome mapping of human skim milk proteins in term and preterm milk. J. Proteome Res., 2012, 11(3), 1696-1714. doi: 10.1021/pr2008797

13. Zolotarskaya, O.Y.; Wagner, A.F.; Beckta, J.M.; Valerie, K.; Wynne, K.J.; Yang, H. Synthesis of Water-Soluble Camptothecin–Polyoxetane Conjugates via Click Chemistry. Mol. Pharmaceutics, 2012, 9(11), 3403–3408. doi: 10.1021/mp3005066

14. Gatzogiannis, E.; Chen, Z.; Wei, L.; Wombacher, R.; Kao, Y.-T.; Yefremov, G.; Cornish, V.W.; Min, W. Mapping protein-specific micro-environments in live cells by fluorescence lifetime imaging of a hybrid genetic-chemical molecular rotor tag. Chem. Commun., 2012, 48, 8694-8696. doi: 10.1039/C2CC33133K

15.Kaastrup, K.; D. Sikes, H.D. Polymerization-based signal amplification under ambient conditions with thirty-five second reaction times. Lab on a Chip, 2012, 12 (20), 4055-4058. doi: 10.1039/C2LC40584A

16. Zhou, K.; Liu, H.; Zhang, S.; Huang, X.; Wang, Y.; Huang, G.; Sumer, B.D.; Gao, J. Multicolored pH-Tunable and Activatable Fluorescence Nanoplatform Responsive to Physiologic pH Stimuli. J. Am. Chem. Soc., 2012, 134 (18), 7803-7811, doi: 10.1021/ja300176w

17. Gatzogiannis, E. Functional Imaging Through Dark State Dynamics. Ph.D. thesis, 2012, Columbia University, USA.

2011

1. Paredes, E.; Das, S.R. Click chemistry for rapid labeling and ligation of RNA. ChemBioChem, 2011, 12(1), 125-131. doi: 10.1002/cbic.201000466.

2. Song, C.-X.; Sun, Y.; Dai, Q.; Lu, X.-Y., Yu, M.; Yang, C.-G.; He, C. Detection of 5-Hydroxymethylcytosine in DNA by Transferring a Keto-Glucose by Using T4 Phage .beta.-Glucosyltransferase. ChemBioChem, 2011, 12(11), 1682–1685. doi: 10.1002/cbic.201100278

3. Ranasinghe, R.T.; Brown, T. Ultrasensitive fluorescence-based methods for nucleic acid detection: towards amplification-free genetic analysis. Chem. Commun., 2011, 47, 3717–3735. doi: 10.1039/c0cc04215c

4. Song, C.-X.; Yu, M.; He, C. Detection of 5-hydroxymethylcytosine in a combined glycosylation restriction analysis (CGRA) using restriction enzyme Taq.alpha.I. BMCL, 2011, 21(17), 5075–5077. doi:10.1016/j.bmcl.2011.03.118

5. Kim, J.-y.; Shim, G.; Choi, H.-w.; Park, J.; Chung, S.W.; Kim, S.; Kim, K.; Kwon, I.C.; Kim, C.-W.; Kim, S.Y.; Yang, V.C.;e Oh, Y.-K.; Byun, Y. Tumor vasculature targeting following co-delivery of heparin-taurocholate conjugate and suberoylanilide hydroxamic acid using cationic nanolipoplex. Biomaterials, 2012, 33(17), 4424-4430. doi: 10.1016/j.biomaterials.2012.02.066

6. He, C.; Song, C. Composition and Methods Related to Modification of 5-Hydroxymethylcytosine (5-HMC). WIPO Patent Application WO/2011/127136

7. Jurs, B. Synthese und Analyse von Liganden des CCR5-Rezeptors, Ph.D. thesis, 2011, University of Hamburg, Germany.

8. Multifunctional Silica Particles as Contrast Agents for Optical and Magnetic Resonance Imaging (Multifunktionale Silica-Partikel als Kontrastmittel fur Optische Bildgebung und Magnetresonanztomographie), Ph.D. thesis, 2011, Eberhard Karls Universität Tübingen, Germany

2010

1. Ranall, M.V.; Gabrielli, B.G.; Gonda, T.J. Adaptation and validation of DNA synthesis detection by fluorescent dye derivatization for high-throughput screening. Biotechniques, 2010, 48(5), 379-386. doi:10.2144/000113410.

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