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Cyclic Tetranuclear and Hexanuclear Palladium(II) Complexes and Their Host-guest Chemistry

Cyclic Tetranuclear and Hexanuclear Palladium(II) Complexes and Their Host-guest Chemistry. Judith A. Walmsley,* Shourong Zhu, Antonio Matilla, Tiffanee G. Donowick, Jessica E. Cramp, Jose Manuel Tercero, and Tatyana Dalrymple. Inorg. Chem. 2007 , 46 , 9945-9953.

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Cyclic Tetranuclear and Hexanuclear Palladium(II) Complexes and Their Host-guest Chemistry

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  1. Cyclic Tetranuclear and Hexanuclear Palladium(II) Complexes and Their Host-guest Chemistry Judith A. Walmsley,* Shourong Zhu, Antonio Matilla, Tiffanee G. Donowick, Jessica E. Cramp, Jose Manuel Tercero, and Tatyana Dalrymple Inorg. Chem.2007, 46, 9945-9953

  2. Supramolecular Coordination Chemistry Hydrogen bonding Metal-ligand coordination π-π stacking Eletrostatic interactions van der Waals forces Hydrophobic interactions Hydrophilic interactions etc. Mirkin, C. A. et al.Angew. Chem. Int. Ed.2001, 40, 2022-2043

  3. Selective Formation of Different Geometric Structures by Appropriate Choice of Corner and Bridging Units Kaiser, A.; Baeuerle, P. Top. Curr. Chem. 2005, 249, 127-201

  4. Extraction of Hydrophobic Species into a Water-Soluble Synthetic Receptor Hooley, R. J.; Van Anda, H. J.; Rebek, J., Jr.J. Am. Chem. Soc.2007, 129, 13464-13473

  5. Molecular Necklace: Quantitative Self-Assembly of a Cyclic Oligorotaxane from Nine Molecules Whang, D.; Park, K.-M.; Heo, J.; Ashton, P.; Kim, K. J. Am. Chem. Soc.1998, 120, 4899-4900

  6. Selective Formation of Different Geometric Structures by Appropriate Choice of Corner and Bridging Units Kaiser, A.; Baeuerle, P. Top. Curr. Chem. 2005, 249, 127-201

  7. Structure of Guanine, Guanosine, and Guanosine 5’-monophosphate (guanosine 5’-monophosphate) Walmsley, J. A. et al. Inorg. Chim. Acta2004, 357, 411-420

  8. Proposed Coordination Process of Pd(en)2+ with 5’GMP Walmsley, J. A. et al. Inorg. Chim. Acta2004, 357, 411-420

  9. Pd(en)-5’GMP System Na2(5’GMP) 8.20 5.95 singlet 8.55 AA’BB’ multiplet 6.55 Figure 1. Structure of [Pd(en)(5’GMP)]4

  10. [Pd(en)(5’GMP)]4 with DSS Guest -2.76 Sodium 3-(trimethylsilyl)-1-propanesulfonate (DSS) γ-(CH2) -0.91, -1.06 ppm (Δδ=1.4) β-(CH2) 1.19, 1.09 ppm (Δδ=0.4) Figure 2. 1H NMR spectra in D2O at pD 5.4 and 25 °C; (A) [Pd(en)-(5’GMP)]4 (20 mM total Pd(II)); (B) mixture of [Pd(en)(5’GMP)]4 and {-[Pd(en)(5’GMP)]6-DSS} (20 mM DSS and 20 mM total Pd(II)); ‘r’ stands for hexamer host-guest complex, ‘u’ stands for free guest ion.

  11. Determined Pd(en)(5’GMP)/DSS ratio by 1H NMR slope = 5.9 ± 0.4, 6.0 ± 0.3 Figure 4. Determination of Pd(en)(5’GMP)/DSS ratio in D2O at pD 5.4 by 1H NMR integrated intensity of the H1’ of host [Pd(en)(5’GMP)]6 and methyl protons of guest DSS; 10 mM total Pd(II) plus variable amounts of DSS.

  12. 31P NMR of Pd(en)(5’GMP)/DSS in D2O hexamer tetramer Figure 3. 31P NMR of 30 mM Pd(en)(5’GMP) in D2O (30 mM total Pd-(II)) with two different concentrations of DSS, pD 5.5; single line at 1.65 ppm is tetramer and two lines at 1.35-1.45 ppm are hexamer with DSS guest.

  13. Nuclear Overhauser Effect SpectroscopY • American physicist Albert Overhauser who hypothesized it in the early • 1950s. The phenomenon was demonstrated by C. P. Slichter and • T. R. Carver in 1953. • Nuclear Overhauser Effect (NOE) arises throughout radio frequency • saturation of one spin, the effect causes the perturbation via dipolar • interactions with further nucleus spins. • NOESY spectra provide information about protons that are 5 • Angstroms or less apart in space. The information is through space • and not through bond.

  14. Partial 1H NOESY Spectrum of [Pd(en)(5’GMP)]n with DSS Guest in D2O H2’, H3’ H8 methyl group H1’ H1’ H8 Figure 5. Partial 1H NOESY spectrum of [Pd(en)(5’GMP)]n(19 mM total Pd(II)) with 5 mM DSS in D2O at pD 5.7 and 25 °C.

  15. Proposed Structure for [Pd(en)(5’GMP)]6 Hexamer with DSS Guest Figure 6. (A) Proposed structure for the hexamer. The 5’GMP units are alternately pointing up and down around the ring. (B) Schematic drawing of [Pd(en)(5’GMP)]6 with DSS guest. The oval represents the Pd(en)-(guanine) and the vertical solid, and wavy lines represent the ribose group. Water molecules may mediate H-bonding between phosphate anions and between phosphate and sulfonate groups.

  16. Strong pH Dependence of Host-guest Formation low pH pH 4.0 bonding of DSS was first observed pH 5.0-5.5 reached a maximum pH 6.0 decreasing pH 7.7 only a small fraction of the DSS was bonded as host pH 5.0-6.0 pH 6.5

  17. 1H NMR Spectra of Pd(en)(5’GMP) with t-Butanol Guest in D2O Pd / t-butanol ratio is 5.9 ± 0.7 Figure 7. 1H NMR spectra of Pd(en)(5’GMP) (20 mM total Pd(II)) and t-butanol in D2O at pD 5.4 and 25 °C. The ‘u’ stands for the resonance from methyl protons of free t-butanol, and ‘r’ stands for methyl protons of guest or H8 and H1’ of hexamer.

  18. 1H NOESY Spectrum of [Pd(en)(5’GMP)]n with t-Butanol Guest in D2O t-BuOH methyl u r H1’ H8

  19. 1H NMR Spectra of Pd(en)(5’GMP) with iso-butanol Guest in D2O Figure 8. 1H NMR resonances of i-butanol as guest in [Pd(en)(5’GMP)]6 in D2O at pD 5.4 and 26 °C; (20 mM total Pd(II) and 10 mM total i-butanol). two doublets equal intensity J = 7.0 Hz heptet H8 H1’ r u r r iso-butanol u u

  20. 1H NMR Spectrum of Pd(en)(5’GMP) with 2-Propanol Guest in D2O 2-PrOH u H8 H1’ u u r r 2-PrOH r

  21. 1H NMR Spectrum of Pd(en)(5’GMP) with TMS Guest in D2O tetramethylsilane (TMS)

  22. Crystal Structure of [Pd(dapol)Cl2] 1,3-diamino-2-propanol (dapol) Figure 10. ORTEP drawing of [Pd(dapo)Cl2] with the atomic numbering scheme; displacement ellipsoids are shown at the 50% level. Table 4. Selected Bond Lengths (Å) and Angles (deg) for [Pd(dapol)Cl2]

  23. Packing Diagram of [Pd(dapol)Cl2] Figure S12. Packing diagram of [Pd(dapol)Cl2]; Color code: Pd (green), Cl (yellow), C (black), N (blue), O (red), H (white).

  24. 1H NMR Spectra of Pd(dapol)(5’GMP) with 2-Propanol Guest in D2O 1,3-diamino-2-propanol (dapol) Figure 9. 1H NMR spectra in D2O at 25 °C. (A) 25 mM Pd(dapol)-(5’GMP), pD 5.4 (25 mM total Pd(II)); (B) mixture of (A) and [Pd(dapol)-(5’GMP)]6-2-PrOH (20 mM total Pd(II), 1.5 mM 2-PrOH), pD 5.8. ‘react’ refers to the host-guest complex.

  25. Chemical Shifts of Methyl Protons of Guests in [Pd(diamine)(5’GMP)]n Table 2. Chemical Shifts of Methyl Protons of Guests in [Pd(diamine)(5’GMP)]na DSS = Sodium 3-(trimethylsilyl)-1-propanesulfonate TMS = Tetramethylsilane TSP = Sodium 3-(trimethysilyl)propionate-d4

  26. Association Constants of [Pd(en)(GMP)]6 Host-Guest Complexes Table 3. K’assoc and Thermodynamic Parameters of [Pd(en)(GMP)]6 Host-Guest Complexes at 26 °C

  27. Conclusions • Upon the introduction of a small organic molecule with hydrophobic interaction sites, the tetramers spontaneously expanded to form a hexamer with one guest molecule strongly incorporated into the central cavity. • We feel that the ease with which the tetramer expanded to the hexamer might be related to unfavorable steric interactions of the 5’GMP at the N7-Pd-N7 corners in the tetramer, rendering the expansion in the presence of a templating agent enegetically favorable. • The guests can be cationic, anionic, or neutral with a high degree of hydrophobic character. They bind strongly to the host in a 1:1 mole ratio, are in slow chemical exchange with uncomplexed guest molecules, and exhibit very large upfield chemical shifts (2.5-3.0 ppm) in the NMR spectra for the most highly affected protons.

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