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1
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85015106657
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Examples of 2D self-assembly of DNA:
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N. C. Seeman Nature 2003 421 427
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(2003)
Nature
, vol.421
, pp. 427
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Seeman, N.C.1
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2
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0032157849
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N. C. Seeman H. Wang X. Yang F. Liu C. Mao W. Sun L. Wenzler Z. Shen R. Sha H. Yan M. H. Wong P. Sa-Ardyen B. Liu H. Qiu X. Li J. Qi S. M. Du Y. Zhang J. E. Mueller T.-J. Fu Y. Wang J. Chen Nanotechnology 1998 9 257
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(1998)
Nanotechnology
, vol.9
, pp. 257
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Seeman, N.C.1
Wang, H.2
Yang, X.3
Liu, F.4
Mao, C.5
Sun, W.6
Wenzler, L.7
Shen, Z.8
Sha, R.9
Yan, H.10
Wong, M.H.11
Sa-Ardyen, P.12
Liu, B.13
Qiu, H.14
Li, X.15
Qi, J.16
Du, S.M.17
Zhang, Y.18
Mueller, J.E.19
Fu, T.-J.20
Wang, Y.21
Chen, J.22
more..
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4
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33645028600
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Examples of 3D self-assembly of DNA:
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P. W. K. Rothemund Nature 2006 440 297
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(2006)
Nature
, vol.440
, pp. 297
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Rothemund, P.W.K.1
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9
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47249089013
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T. Maruyama H. Yamamura M. Hiraki Y. Kemori H. Takata M. Goto Colloids Surf., B 2008 66 119
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(2008)
Colloids Surf., B
, vol.66
, pp. 119
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Maruyama, T.1
Yamamura, H.2
Hiraki, M.3
Kemori, Y.4
Takata, H.5
Goto, M.6
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11
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52349119302
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Examples where DNA is used to organize nanoparticles and proteins:
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M. Banchelli F. Betti D. Berti G. Caminati F. Baldelli Bombelli T. Brown L. M. Wilhelmsson B. Norden P. Baglioni J. Phys. Chem. B 2008 112 10942
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(2008)
J. Phys. Chem. B
, vol.112
, pp. 10942
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Banchelli, M.1
Betti, F.2
Berti, D.3
Caminati, G.4
Baldelli Bombelli, F.5
Brown, T.6
Wilhelmsson, L.M.7
Norden, B.8
Baglioni, P.9
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18
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61749096400
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P. G. A. Janssen S. Jabbari-Farouji M. Surin X. Vila J. C. Gielen T. F. A. de Greef M. R. J. Vos P. H. H. Bomans N. A. J. M. Sommerdijk P. C. M. Christianen Ph. Leclère R. Lazzaroni P. van der Schoot E. W. Meijer A. P. H. J. Schenning J. Am. Chem. Soc. 2009 131 1222
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(2009)
J. Am. Chem. Soc.
, vol.131
, pp. 1222
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Janssen, P.G.A.1
Jabbari-Farouji, S.2
Surin, M.3
Vila, X.4
Gielen, J.C.5
De Greef, T.F.A.6
Vos, M.R.J.7
Bomans, P.H.H.8
Sommerdijk, N.A.J.M.9
Christianen, P.C.M.10
Leclère, Ph.11
Lazzaroni, R.12
Van Der Schoot, P.13
Meijer, E.W.14
Schenning, A.P.H.J.15
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28
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0017359465
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For the description of DNA hybridization usually for simplicity a two-state model is used. See references 7 and 8, and for example:
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D. Pörschke Mol. Biol., Biochem. Biophys. 1977 24 191
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(1977)
Mol. Biol., Biochem. Biophys.
, vol.24
, pp. 191
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Pörschke, D.1
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34
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0015883168
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For hybridization studies of two single strands that bind in a 1: 1 fashion and predictions of the thermodynamic parameters, see for example:
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G. W. Hoffmann D. Pörschke Biopolymers 1973 12 1611
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(1973)
Biopolymers
, vol.12
, pp. 1611
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Hoffmann, G.W.1
Pörschke, D.2
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44
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0024208202
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For each data point, the fraction of occupied binding sites of the T40, , at a given temperature is calculated from the temperature-dependent UV-vis spectroscopy measurement It should be noted that for dA20 and dA40 binding to T40 or T20, double strands longer than T40 and T20, respectively, can be formed
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S. T. Gudibande S. D. Jayasena M. J. Behe Biopolymers 1988 27 1905
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(1988)
Biopolymers
, vol.27
, pp. 1905
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Gudibande, S.T.1
Jayasena, S.D.2
Behe, M.J.3
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45
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0023406843
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We have use the McGhee-von Hippel model to obtain information on the host-guest and guest-guest interaction, but these attempts failed. See:
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L. A. Marky K. J. Breslauer Biopolymers 1987 26 1601
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(1987)
Biopolymers
, vol.26
, pp. 1601
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Marky, L.A.1
Breslauer, K.J.2
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47
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4043122531
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R. Iwaura K. Yoshida M. Masuda M. Ohnishi-Kameyama M. Yoshida T. Shimizu Angew. Chem., Int. Ed. 2003 42 1009
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(2003)
Angew. Chem., Int. Ed.
, vol.42
, pp. 1009
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Iwaura, R.1
Yoshida, K.2
Masuda, M.3
Ohnishi-Kameyama, M.4
Yoshida, M.5
Shimizu, T.6
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