Literature DB >> 31391981

Crystal structure of methyl α-l-rhamno-pyranosyl-(1→2)-α-l-rhamno-pyran-oside monohydrate.

Lars Eriksson1, Göran Widmalm2.   

Abstract

The title compound, C13H24O9·H2O, a structural model for part of bacterial O-anti-gen polysaccharides from Shigella flexneri and Escherichia coli, crystallizes with four independent disaccharide mol-ecules and four water mol-ecules in the asymmetric unit. The conformation at the glycosidic linkage joining the two rhamnosyl residues is described by the torsion angles φH of 39, 30, 37 and 37°, and ψH of -32, -35, -31 and -32°, which are the major conformation region known to be populated in an aqueous solution. The hexo-pyran-ose rings have the 1 C 4 chair conformation. In the crystal, the disaccharide and water mol-ecules are associated through O-H⋯O hydrogen bonds, forming a layer parallel to the bc plane. The layers stack along the a axis via hydro-phobic inter-actions between the methyl groups.

Entities:  

Keywords:  carbohydrates; conformation; crystal structure; disaccharide; packing

Year:  2019        PMID: 31391981      PMCID: PMC6658941          DOI: 10.1107/S2056989019006935

Source DB:  PubMed          Journal:  Acta Crystallogr E Crystallogr Commun


Chemical context

The title disaccharide compound is a structural model for part of bacterial O-anti­gen polysaccharides from Shigella flexneri (Kubler-Kielb et al., 2007 ▸) and Escherichia coli (Marie et al., 1998 ▸). In the title compound, inter-residue hydrogen bonding is not possible, which thus gives the opportunity to study conformational preferences at the glycosidic linkage devoid of the hydrogen bonds. Furthermore, the major conformation in water differs from that in dimethyl sulfoxide as determined by NMR spectroscopy and mol­ecular dynamics simulations (Pendrill et al., 2016 ▸). These conformations can be compared to the present crystal structure obtained from a water:ethanol (1:1) mixed solution.

Structural commentary

The asymmetric unit of the title compound contains four independent disaccharides of closely similar conformation, shown in Figs. 1 ▸–3 ▸ ▸, where the hexo­pyran­ose rings have the 1 C 4 chair conformation. In the disaccharide mol­ecule, there are three major degrees of freedom with the glycosidic torsion angles of φH, ψH and φH(C7), which are defined, respectively, by H1A—C1A—O2B—C2B, C1A—O2B—C2B—H2B and H1B—C1B—O7B—C7B. These torsion angles are (I) φH =39°, ψH = −32° and φH(C7) = 49°, (II) φH = 30°, ψH −35° and φH(C7) = 52°, (III) φH = 36°, ψH = −31° and φH(C7) = 51°, and (IV) φH = 37°, ψH = −32° and φH(C7) = 51°, where (I)–(IV) correspond to the four independent disaccharide mol­ecules 1–4, respectively, in Fig. 2 ▸. The average φH, ψH and φH(C7) angles are 35 (4), −33 (2) and 51 (1)°, respectively. The φH torsion angle is governed by the exo-anomeric effect and should be approximately 40° for an α-l-sugar, which is also the case in the title rhamnose-containing disaccharide (Widmalm et al., 1992 ▸). The ψH torsion angle depends on the stereochemistry at or close to the glycosidic linkage. In solution it can take both positive and negative values, depending on the solvent that the solute is dissolved in (Pendrill et al., 2016 ▸). Inter­estingly, in the crystal of the title compound, the ψH torsion angle is negative like the major conformer in water solution (Pendrill et al., 2016 ▸). This conformation causes the three methyl groups to be positioned on one side of the mol­ecule. In the crystal of a rhamnose-containing tris­accharide having the glycosidic α-(1 → 2)-linkage (Eriksson & Widmalm, 2012 ▸), quite similar torsion angles of φH = 48° and ψH = −29° were observed.
Figure 1

The structure of one of the title disaccharide mol­ecules, disaccharide 1, showing the atom-labelling scheme. The third character of the atom label denotes the rhamnose residue A or B in each disaccharide and the fourth character indicates each independent disaccharide entity. Displacement ellipsoids are drawn at the 50% probability level.

Figure 2

The four independent disaccharide mol­ecules, 1–4, in the asymmetric unit together with four adjacent water mol­ecules.

Figure 3

Overlays between pairs of the four independent mol­ecules with minimal root-mean-square deviations (RMSD): (a) 1 and 2, (b) 1 and 3, (c) 1 and 4, (d) 2 and 3, (e) 2 and 4, (f) 3 and 4.

Supra­molecular features

Hydro­philic inter­actions dominate in a network of O—H⋯O hydrogen bonds that connect the disaccharide and water mol­ecules (Table 1 ▸), forming a layer parallel to the bc plane, while hydro­phobic inter­actions between the methyl groups dominate in the bc plane at x = 0.5 (Figs. 2 ▸ and 4 ▸). A DFT optimization of the title structure has been performed with plane waves and pseudo potentials using NWChem (Valiev et al., 2010 ▸). The major differences between the optimized and observed structures are that the O—H distances are slightly longer in the optimized structure than the experimental values and some geometrical details, e.g. torsion angles of hydroxyl groups. The hydrogen-bonding scheme obtained from the DFT-optimized structure was similar, with minor differences between the experimental structure and the DFT-optimized version.
Table 1

Hydrogen-bond geometry (Å, °)

D—H⋯A D—HH⋯A DA D—H⋯A
O2A1—H2A2⋯O20.841.962.770 (9)161
O3A1—H3A2⋯O4A20.842.593.366 (10)154
O3B1—H3B2⋯O3A3i 0.841.952.766 (8)164
O4B1—H4B2⋯O1ii 0.841.892.693 (10)158
O2A2—H2A4⋯O1iii 0.842.042.834 (10)159
O3A2—H3A4⋯O3ii 0.841.852.647 (9)159
O4A2—H4A4⋯O4A10.842.092.862 (8)152
O3B2—H3B4⋯O3A2iv 0.842.062.710 (7)133
O4B2—H4B4⋯O20.842.202.952 (8)150
O2A3—H2A6⋯O4B1ii 0.841.982.791 (8)161
O3A3—H3A6⋯O3ii 0.841.922.741 (9)165
O4A3—H4A6⋯O4A40.842.132.731 (9)128
O3B3—H3B6⋯O2A1iii 0.842.583.309 (8)146
O3B3—H3B6⋯O3A1iii 0.842.132.855 (8)145
O4B3—H4B6⋯O2A1iii 0.842.002.754 (9)149
C3A4—H3A7⋯O3A31.002.563.431 (10)146
O3A4—H3A8⋯O3B4i 0.842.082.761 (8)138
O4A4—H4A8⋯O4A10.842.052.717 (9)136
O3B4—H3B8⋯O3B1ii 0.842.022.843 (7)168
O4B4—H4B8⋯O2A4ii 0.842.082.859 (8)155
O1—H12⋯O4B3iv 0.86 (1)1.86 (2)2.718 (10)174 (7)
O2—H21⋯O4B4v 0.85 (1)2.29 (4)3.030 (9)145 (6)
O2—H22⋯O5A3v 0.85 (1)2.62 (2)3.461 (9)169 (5)
O3—H31⋯O3A4i 0.85 (1)2.00 (4)2.695 (8)139 (5)
O3—H32⋯O40.85 (1)1.80 (3)2.582 (13)152 (7)
O4—H41⋯O7B10.85 (1)2.29 (3)3.037 (14)147 (5)
O4—H42⋯O7B3vi 0.85 (1)2.26 (3)3.021 (14)148 (4)

Symmetry codes: (i) ; (ii) ; (iii) ; (iv) ; (v) ; (vi) .

Figure 4

A packing diagram of the title compound viewed along the b axis, showing hydro­philic and hydro­phobic contacts between layers. The hydro­philic bound layers extend parallel to the bc plane, while the layers pack with hydro­phobic inter­actions at x = 0.5.

Database survey

A search for related compounds in the CSD (2019 release; Groom et al., 2016 ▸) gave only one hit with the rhamnose dimer as fragment, XEBQAY (Eriksson & Widmalm, 2012 ▸), with a good fit to the three-dimensional arrangement of the disaccharide element. A search using only the monomer skeleton without hydroxyl H atoms produced 178 hits, but most of these were not relevant for comparison with the title mol­ecule.

Synthesis and crystallization

The title compound was synthesized according to the published procedures (Norberg et al., 1986 ▸), where the rhamnosyl residues have the L absolute configuration. Colourless prismatic single crystals were obtained by slow evaporation from a water:ethanol (1:1) mixture solution at ambient temperature.

Refinement

Crystal data, data collection and structural refinement details are summarized in Table 2 ▸. Diffraction data from three separate crystals of the approximately same size were merged using the BASF instruction available in the SHELXL program. Although each single crystal showed considerable disorder, the three crystals together provided a complete data set at the expense of a rather high inter­nal R value. Weak ISOR restraints were applied for all non-H atoms. H atoms in the disaccharide mol­ecules were added geometrically (C—H = 1.00 or 0.98 Å and O—H = 0.84 Å) and treated as riding with U iso(H) = 1.2–1.5U eq(C,O). The O—H bond and H⋯H distances in the water mol­ecules were restrained to 0.85 (1) and 1.34 (1) Å, respectively. The orientation of each water mol­ecule was adjusted and restrained with additional DFIX commands using parameters derived from a solid state DFT optimization of the crystal structure.
Table 2

Experimental details

Crystal data
Chemical formulaC13H24O9·H2O
M r 342.34
Crystal system, space groupMonoclinic, P21
Temperature (K)100
a, b, c (Å)13.936 (3), 15.501 (3), 15.988 (3)
β (°)105.92 (16)
V3)3321 (12)
Z 8
Radiation typeCu Kα
μ (mm−1)1.02
Crystal size (mm)0.10 × 0.07 × 0.03
 
Data collection
DiffractometerBruker D8 Advance
Absorption correctionMulti-scan (APEX3; Bruker, 2017)
T min, T max 0.90, 0.97
No. of measured, independent and observed [I > 2σ(I)] reflections42501, 11996, 4360
R int 0.158
(sin θ/λ)max−1)0.602
 
Refinement
R[F 2 > 2σ(F 2)], wR(F 2), S 0.075, 0.173, 0.85
No. of reflections11996
No. of parameters885
No. of restraints571
H-atom treatmentH atoms treated by a mixture of independent and constrained refinement
Δρmax, Δρmin (e Å−3)0.44, −0.30
Absolute structureFlack x determined using 1400 quotients [(I +)−(I )]/[(I +)+(I )] (Parsons et al., 2013)
Absolute structure parameter−0.03 (18)

Computer programs: APEX3 (Bruker, 2017 ▸), CrysAlis PRO (Agilent, 2014 ▸), SHELXT (Sheldrick, 2015a ▸), SHELXL2016 (Sheldrick, 2015b ▸), DIAMOND (Brandenburg, 1999 ▸), Mercury (Macrae et al., 2008 ▸), PLATON (Spek, 2009 ▸), enCIFer (Allen et al., 2004 ▸) and publCIF (Westrip, 2010 ▸).

Crystal structure: contains datablock(s) I, global. DOI: 10.1107/S2056989019006935/is5512sup1.cif Structure factors: contains datablock(s) I. DOI: 10.1107/S2056989019006935/is5512Isup2.hkl CCDC reference: 1915954 Additional supporting information: crystallographic information; 3D view; checkCIF report
C13H24O9·H2OF(000) = 1472
Mr = 342.34Dx = 1.369 Mg m3
Monoclinic, P21Cu Kα radiation, λ = 1.54184 Å
a = 13.936 (3) ÅCell parameters from 29997 reflections
b = 15.501 (3) Åθ = 2.8–68.2°
c = 15.988 (3) ŵ = 1.02 mm1
β = 105.92 (16)°T = 100 K
V = 3321 (12) Å3Prism, colourless
Z = 80.10 × 0.07 × 0.03 mm
Bruker D8 Advance diffractometer11996 independent reflections
Radiation source: Incotec 1myS4360 reflections with I > 2σ(I)
Detector resolution: 10 pixels mm-1Rint = 0.158
ω scans at different φθmax = 68.3°, θmin = 2.9°
Absorption correction: multi-scan (APEX3; Bruker, 2017)h = −16→16
Tmin = 0.90, Tmax = 0.97k = −18→18
42501 measured reflectionsl = −19→12
Refinement on F2Hydrogen site location: mixed
Least-squares matrix: fullH atoms treated by a mixture of independent and constrained refinement
R[F2 > 2σ(F2)] = 0.075w = 1/[σ2(Fo2) + (0.0773P)2] where P = (Fo2 + 2Fc2)/3
wR(F2) = 0.173(Δ/σ)max < 0.001
S = 0.85Δρmax = 0.44 e Å3
11996 reflectionsΔρmin = −0.30 e Å3
885 parametersAbsolute structure: Flack x determined using 1400 quotients [(I+)-(I-)]/[(I+)+(I-)] (Parsons et al., 2013)
571 restraintsAbsolute structure parameter: −0.03 (18)
Geometry. All esds (except the esd in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell esds are taken into account individually in the estimation of esds in distances, angles and torsion angles; correlations between esds in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell esds is used for estimating esds involving l.s. planes.
xyzUiso*/Ueq
C1A10.1588 (5)0.4641 (5)0.4294 (5)0.055 (2)
H1A10.1279840.4062810.4321760.067*
C2A10.0970 (6)0.5092 (5)0.3498 (5)0.064 (2)
H2A10.0307680.5244700.3587590.076*
C3A10.1466 (7)0.5887 (5)0.3330 (5)0.067 (3)
H3A10.1463760.6307960.3803280.080*
C4A10.2544 (7)0.5734 (5)0.3331 (5)0.069 (3)
H4A10.2553870.5348580.2831780.083*
C5A10.3088 (6)0.5291 (6)0.4169 (5)0.065 (2)
H5A10.3083270.5678290.4667950.078*
C6A10.4145 (5)0.5059 (7)0.4220 (6)0.096 (3)
H6A10.4393480.4643910.4691700.144*
H6A20.4559100.5580380.4333400.144*
H6A30.4175290.4802470.3667520.144*
O2A10.0818 (5)0.4538 (4)0.2760 (3)0.0843 (19)
H2A20.1115480.4068350.2911240.126*
O3A10.0921 (5)0.6257 (4)0.2525 (3)0.095 (2)
H3A20.1136730.6755250.2479760.142*
O4A10.3012 (5)0.6531 (4)0.3232 (4)0.094 (2)
H4A20.3613270.6518050.3524380.141*
O5A10.2583 (4)0.4503 (3)0.4257 (3)0.0609 (15)
C1B10.2893 (6)0.4581 (6)0.6248 (5)0.074 (3)
H1B10.3236670.4445390.5791230.089*
C2B10.1752 (6)0.4588 (5)0.5821 (5)0.054 (2)
H2B10.1507820.3985100.5674590.064*
C3B10.1192 (5)0.4997 (5)0.6395 (5)0.052 (2)
H3B10.1223950.4592610.6889190.062*
C4B10.1666 (6)0.5834 (5)0.6776 (5)0.054 (2)
H4B10.1611540.6263390.6299190.065*
C5B10.2773 (6)0.5682 (6)0.7247 (5)0.060 (2)
H5B10.2827560.5237720.7710800.072*
C6B10.3288 (6)0.6512 (6)0.7658 (6)0.089 (3)
H6B10.4013460.6433630.7812270.133*
H6B20.3083150.6646620.8182400.133*
H6B30.3097800.6988090.7241390.133*
C7B10.4048 (8)0.3660 (7)0.7137 (6)0.127 (4)
H7B10.4253290.3383450.6662050.191*
H7B20.4131960.3252960.7620720.191*
H7B30.4462030.4171100.7334970.191*
O7B10.3057 (5)0.3903 (4)0.6845 (4)0.093 (2)
O2B10.1544 (3)0.5105 (3)0.5036 (3)0.0533 (14)
O3B10.0180 (3)0.5117 (4)0.5954 (3)0.0612 (16)
H3B2−0.0169890.5030390.6297790.092*
O4B10.1147 (4)0.6154 (4)0.7377 (4)0.0773 (17)
H4B20.1121700.6695160.7349960.116*
O5B10.3246 (4)0.5372 (4)0.6627 (3)0.0715 (17)
C1A20.1581 (6)0.6656 (5)−0.0379 (5)0.054 (2)
H1A20.1417650.655735−0.1020510.065*
C2A20.0717 (5)0.7139 (5)−0.0176 (5)0.053 (2)
H2A30.0111010.676328−0.0320920.064*
C3A20.0991 (6)0.7355 (5)0.0768 (5)0.056 (2)
H3A30.1013350.6803920.1098260.067*
C4A20.2001 (6)0.7773 (5)0.1074 (5)0.056 (2)
H4A30.1952940.8361530.0810660.067*
C5A20.2795 (6)0.7281 (5)0.0799 (5)0.063 (3)
H5A20.2921570.6722680.1124510.075*
C6A20.3764 (6)0.7779 (7)0.0972 (7)0.108 (4)
H6A40.4207970.7495810.0675840.162*
H6A50.4085520.7793930.1599340.162*
H6A60.3626180.8369380.0753040.162*
O2A20.0514 (4)0.7907 (3)−0.0689 (3)0.0613 (15)
H2A40.0543950.779870−0.1196090.092*
O3A20.0224 (4)0.7870 (4)0.0924 (4)0.0822 (18)
H3A40.0183150.7780830.1430860.123*
O4A20.2259 (5)0.7869 (4)0.1991 (3)0.099 (2)
H4A40.2590620.7438560.2227440.148*
O5A20.2486 (4)0.7104 (3)−0.0111 (3)0.0638 (16)
C1B20.3082 (5)0.5083 (5)−0.0125 (5)0.060 (2)
H1B20.3353410.566739−0.0195390.072*
C2B20.1929 (5)0.5118 (5)−0.0371 (5)0.055 (2)
H2B20.1666290.518370−0.1015260.066*
C3B20.1505 (5)0.4336 (5)−0.0098 (4)0.051 (2)
H3B30.1632010.384344−0.0457010.061*
C4B20.1956 (5)0.4125 (5)0.0827 (5)0.050 (2)
H4B30.1822630.4599980.1204210.060*
C5B20.3071 (6)0.4009 (6)0.0978 (5)0.070 (3)
H5B20.3186400.3544200.0583080.084*
C6B20.3625 (7)0.3789 (7)0.1885 (5)0.101 (4)
H6B40.4338460.3896290.1971080.152*
H6B50.3521090.3178180.1994250.152*
H6B60.3381440.4145730.2289870.152*
C7B20.4356 (6)0.4518 (7)−0.0634 (6)0.100 (3)
H7B40.4561840.511146−0.0704200.150*
H7B50.4495670.415255−0.1086810.150*
H7B60.4726850.430111−0.0060150.150*
O7B20.3331 (4)0.4500 (4)−0.0705 (3)0.0729 (17)
O2B20.1629 (4)0.5847 (3)0.0046 (3)0.0569 (14)
O3B20.0439 (4)0.4440 (3)−0.0269 (3)0.0600 (15)
H3B40.0149090.415542−0.0713420.090*
O4B20.1553 (4)0.3332 (3)0.1036 (3)0.0721 (17)
H4B40.1436500.3376950.1522310.108*
O5B20.3466 (4)0.4799 (4)0.0755 (3)0.0722 (17)
C1A30.1619 (5)1.1095 (5)0.1451 (5)0.051 (2)
H1A30.1353211.1684770.1266270.061*
C2A30.0957 (6)1.0671 (5)0.1914 (4)0.052 (2)
H2A50.0291951.0560760.1491950.062*
C3A30.1369 (5)0.9837 (5)0.2338 (5)0.052 (2)
H3A50.1352030.9406730.1868050.063*
C4A30.2418 (5)0.9938 (5)0.2858 (5)0.054 (2)
H4A50.2429861.0295220.3381500.065*
C5A30.3051 (6)1.0385 (6)0.2349 (5)0.066 (2)
H5A30.3075440.9995640.1856900.079*
C6A30.4115 (6)1.0609 (7)0.2829 (6)0.106 (4)
H6A70.4387331.1006500.2474900.159*
H6A80.4518561.0082130.2938320.159*
H6A90.4130121.0885160.3383720.159*
O2A30.0834 (4)1.1262 (3)0.2569 (3)0.0685 (16)
H2A60.0293251.1157950.2686370.103*
O3A30.0777 (5)0.9516 (4)0.2858 (3)0.0782 (18)
H3A60.0505090.9052430.2644220.117*
O4A30.2877 (5)0.9112 (4)0.3149 (4)0.085 (2)
H4A60.2865900.9024220.3664630.128*
O5A30.2605 (4)1.1172 (3)0.1981 (3)0.0632 (15)
C1B30.2909 (6)1.1088 (7)0.0104 (6)0.073 (3)
H1B30.3256511.1210000.0727720.088*
C2B30.1787 (5)1.1089 (6)−0.0019 (4)0.056 (2)
H2B30.1552921.169631−0.0001280.067*
C3B30.1196 (6)1.0669 (5)−0.0853 (4)0.052 (2)
H3B50.1209801.108243−0.1330060.062*
C4B30.1680 (6)0.9869 (6)−0.1041 (4)0.062 (2)
H4B50.1643350.941940−0.0602920.075*
C5B30.2751 (6)1.0024 (7)−0.1007 (5)0.074 (3)
H5B30.2781361.049188−0.1428970.089*
C6B30.3292 (7)0.9238 (6)−0.1216 (6)0.101 (4)
H6B70.3998560.937750−0.1130550.152*
H6B80.2994870.906787−0.1822220.152*
H6B90.3232940.876152−0.0830500.152*
C7B30.4102 (8)1.1990 (8)−0.0228 (8)0.148 (5)
H7B70.4355201.2148030.0387170.222*
H7B80.4193581.247511−0.0591130.222*
H7B90.4469931.148735−0.0348510.222*
O7B30.3070 (5)1.1785 (4)−0.0417 (4)0.105 (2)
O2B30.1578 (3)1.0598 (3)0.0698 (3)0.0567 (15)
O3B30.0181 (4)1.0544 (4)−0.0898 (3)0.0655 (16)
H3B6−0.0154651.052127−0.1421750.098*
O4B30.1184 (4)0.9558 (4)−0.1893 (3)0.089 (2)
H4B60.0579050.969962−0.2020610.133*
O5B30.3258 (4)1.0321 (4)−0.0136 (3)0.0769 (18)
C1A40.1636 (6)0.9094 (5)0.6101 (5)0.058 (2)
H1A40.1409140.9200530.6633210.070*
C2A40.0871 (6)0.8537 (5)0.5488 (5)0.052 (2)
H2A70.0244050.8880220.5269670.062*
C3A40.1254 (7)0.8283 (5)0.4709 (5)0.064 (3)
H3A70.1270310.8818350.4364130.076*
C4A40.2312 (6)0.7923 (6)0.4990 (5)0.066 (2)
H4A70.2301440.7346600.5268070.079*
C5A40.2970 (6)0.8528 (5)0.5643 (5)0.065 (3)
H5A40.3043190.9080450.5343810.078*
C6A40.4013 (6)0.8124 (7)0.6014 (6)0.101 (4)
H6AX0.3952870.7593640.6329660.151*
H6AY0.4445270.8533530.6412540.151*
H6AZ0.4303580.7988740.5536760.151*
O2A40.0650 (4)0.7793 (3)0.5922 (3)0.0698 (16)
H2A80.1183360.7579900.6232570.105*
O3A40.0571 (5)0.7715 (4)0.4175 (3)0.0838 (19)
H3A80.0585970.7239410.4429860.126*
O4A40.2691 (5)0.7829 (4)0.4265 (4)0.104 (2)
H4A80.2836530.7309580.4214950.157*
O5A40.2571 (4)0.8711 (3)0.6351 (3)0.0576 (15)
C1B40.3105 (6)1.0699 (6)0.6460 (5)0.066 (3)
H1B40.3395481.0113050.6624360.079*
C2B40.1981 (6)1.0627 (5)0.6225 (5)0.052 (2)
H2B40.1769321.0546850.6769620.062*
C3B40.1467 (6)1.1400 (5)0.5753 (5)0.052 (2)
H3B70.1591541.1885060.6181960.062*
C4B40.1886 (6)1.1666 (5)0.5045 (5)0.055 (2)
H4B70.1763631.1196960.4598380.066*
C5B40.2989 (6)1.1816 (5)0.5376 (6)0.063 (3)
H5B40.3118401.2255430.5851600.076*
C6B40.3527 (8)1.2078 (7)0.4718 (6)0.104 (4)
H6BX0.4244301.1974860.4957910.156*
H6BY0.3411001.2691600.4582110.156*
H6BZ0.3277131.1736500.4186930.156*
C7B40.4500 (7)1.1195 (7)0.7541 (6)0.133 (5)
H7BX0.4710741.0590440.7615090.199*
H7BY0.4683861.1485600.8106870.199*
H7BZ0.4830551.1481710.7148600.199*
O7B40.3427 (5)1.1237 (4)0.7172 (4)0.091 (2)
O2B40.1664 (4)0.9902 (3)0.5675 (3)0.0579 (15)
O3B40.0422 (4)1.1278 (3)0.5471 (3)0.0642 (15)
H3B80.0287541.0880560.5100290.096*
O4B40.1443 (4)1.2441 (3)0.4640 (4)0.0746 (17)
H4B80.0828661.2435900.4598890.112*
O5B40.3421 (4)1.0997 (4)0.5733 (4)0.0736 (17)
O1−0.1048 (6)0.2846 (5)0.2275 (5)0.147 (3)
H11−0.0401 (12)0.279 (3)0.245 (7)0.177*
H12−0.111 (3)0.3377 (16)0.211 (5)0.177*
O20.1643 (6)0.2903 (4)0.2855 (4)0.116 (2)
H210.186 (5)0.277 (4)0.3388 (10)0.139*
H220.190 (4)0.253 (3)0.259 (2)0.139*
O30.0171 (6)0.2961 (5)0.7551 (4)0.131 (3)
H31−0.005 (4)0.263 (3)0.712 (2)0.157*
H320.076 (2)0.278 (4)0.779 (3)0.157*
O40.2092 (8)0.2831 (10)0.7982 (8)0.249 (6)
H410.234 (3)0.293 (4)0.7562 (19)0.299*
H420.246 (4)0.243 (2)0.828 (2)0.299*
U11U22U33U12U13U23
C1A10.050 (5)0.059 (6)0.058 (5)0.001 (5)0.017 (4)0.009 (5)
C2A10.088 (6)0.061 (6)0.042 (5)0.005 (5)0.018 (5)0.000 (5)
C3A10.117 (8)0.030 (5)0.058 (5)−0.002 (5)0.032 (5)0.000 (4)
C4A10.116 (7)0.034 (6)0.066 (6)−0.015 (5)0.039 (5)−0.004 (5)
C5A10.080 (6)0.063 (6)0.058 (5)−0.012 (5)0.028 (5)−0.011 (5)
C6A10.044 (6)0.142 (10)0.102 (7)−0.007 (6)0.018 (5)−0.018 (7)
O2A10.124 (5)0.068 (4)0.052 (3)0.008 (4)0.010 (3)−0.020 (3)
O3A10.159 (6)0.063 (4)0.057 (4)0.017 (4)0.020 (4)0.026 (3)
O4A10.134 (6)0.072 (5)0.079 (4)−0.029 (4)0.036 (4)−0.011 (4)
O5A10.088 (4)0.039 (3)0.060 (3)0.005 (3)0.027 (3)0.004 (3)
C1B10.076 (7)0.080 (7)0.059 (6)0.034 (6)0.007 (5)0.020 (6)
C2B10.065 (6)0.047 (5)0.049 (5)0.001 (4)0.015 (4)0.001 (4)
C3B10.057 (5)0.060 (6)0.037 (4)−0.010 (5)0.010 (4)−0.005 (4)
C4B10.072 (6)0.052 (6)0.040 (4)−0.010 (5)0.018 (4)0.000 (4)
C5B10.063 (6)0.070 (6)0.045 (5)−0.010 (5)0.012 (4)0.003 (5)
C6B10.077 (7)0.063 (7)0.110 (7)−0.016 (5)−0.001 (6)−0.022 (6)
C7B10.124 (10)0.112 (10)0.104 (8)0.040 (8)−0.041 (7)0.002 (7)
O7B10.118 (6)0.069 (4)0.075 (4)0.016 (4)−0.002 (4)0.013 (4)
O2B10.075 (3)0.055 (4)0.030 (3)0.011 (3)0.014 (3)0.003 (3)
O3B10.053 (3)0.080 (4)0.053 (3)−0.015 (3)0.018 (3)−0.002 (3)
O4B10.096 (4)0.071 (4)0.073 (4)−0.006 (4)0.036 (3)−0.021 (3)
O5B10.074 (4)0.084 (5)0.059 (3)−0.003 (3)0.023 (3)−0.004 (3)
C1A20.067 (6)0.050 (6)0.045 (5)−0.012 (5)0.015 (4)0.009 (4)
C2A20.042 (5)0.050 (6)0.070 (6)−0.010 (4)0.020 (4)0.009 (5)
C3A20.077 (6)0.054 (6)0.043 (5)0.006 (5)0.025 (5)0.004 (4)
C4A20.086 (6)0.037 (5)0.044 (5)0.008 (5)0.017 (5)0.003 (4)
C5A20.066 (6)0.056 (6)0.056 (6)−0.005 (5)0.000 (5)0.010 (5)
C6A20.052 (6)0.117 (8)0.140 (9)−0.019 (6)0.000 (6)−0.003 (8)
O2A20.102 (4)0.042 (3)0.042 (3)0.014 (3)0.022 (3)0.018 (3)
O3A20.115 (5)0.067 (4)0.080 (4)0.027 (4)0.055 (4)0.011 (4)
O4A20.185 (7)0.047 (4)0.047 (4)0.016 (4)0.002 (4)−0.008 (3)
O5A20.067 (4)0.056 (4)0.076 (4)0.003 (3)0.032 (3)0.006 (3)
C1B20.062 (6)0.057 (6)0.064 (6)0.010 (5)0.021 (5)−0.012 (5)
C2B20.058 (5)0.059 (6)0.050 (5)0.005 (5)0.017 (4)0.001 (5)
C3B20.051 (6)0.055 (6)0.042 (5)0.000 (4)0.007 (4)0.002 (4)
C4B20.055 (6)0.048 (6)0.044 (5)−0.007 (4)0.008 (4)0.004 (4)
C5B20.070 (7)0.065 (7)0.071 (6)0.000 (5)0.011 (5)0.004 (5)
C6B20.090 (8)0.126 (9)0.066 (6)0.007 (7)−0.014 (5)0.020 (6)
C7B20.064 (6)0.123 (9)0.123 (8)0.012 (6)0.044 (6)0.005 (7)
O7B20.087 (4)0.072 (4)0.065 (3)0.012 (3)0.030 (3)−0.003 (3)
O2B20.079 (4)0.043 (4)0.055 (3)0.004 (3)0.027 (3)−0.008 (3)
O3B20.057 (4)0.055 (4)0.060 (3)−0.003 (3)0.002 (3)−0.010 (3)
O4B20.096 (4)0.055 (4)0.066 (4)0.002 (3)0.023 (3)0.008 (3)
O5B20.078 (4)0.073 (4)0.056 (3)−0.007 (3)0.003 (3)−0.011 (3)
C1A30.045 (5)0.067 (6)0.045 (5)−0.015 (4)0.022 (4)−0.014 (4)
C2A30.067 (5)0.052 (6)0.038 (4)0.001 (5)0.017 (4)−0.013 (4)
C3A30.067 (6)0.044 (6)0.053 (5)0.005 (4)0.028 (5)−0.004 (4)
C4A30.057 (5)0.051 (6)0.052 (5)0.009 (5)0.012 (4)0.003 (4)
C5A30.070 (6)0.053 (6)0.079 (6)0.000 (5)0.028 (5)−0.014 (5)
C6A30.054 (6)0.161 (11)0.097 (7)−0.009 (7)0.011 (5)−0.005 (7)
O2A30.074 (4)0.062 (4)0.078 (4)0.001 (3)0.036 (3)−0.005 (3)
O3A30.121 (5)0.059 (4)0.068 (4)−0.016 (4)0.049 (3)0.008 (3)
O4A30.113 (5)0.073 (5)0.066 (4)0.021 (4)0.018 (4)0.001 (3)
O5A30.080 (4)0.049 (4)0.062 (3)−0.010 (3)0.023 (3)−0.002 (3)
C1B30.062 (6)0.094 (8)0.075 (6)−0.020 (6)0.036 (5)−0.009 (6)
C2B30.065 (6)0.064 (6)0.043 (5)−0.002 (5)0.023 (4)0.014 (4)
C3B30.061 (6)0.060 (6)0.036 (4)0.003 (5)0.014 (4)0.002 (4)
C4B30.080 (6)0.068 (6)0.040 (5)0.019 (5)0.018 (4)−0.008 (5)
C5B30.068 (6)0.110 (8)0.049 (5)0.013 (6)0.025 (5)0.009 (5)
C6B30.077 (7)0.119 (9)0.109 (7)0.040 (6)0.027 (6)−0.031 (7)
C7B30.146 (10)0.129 (11)0.205 (13)−0.053 (8)0.111 (9)−0.018 (9)
O7B30.117 (5)0.099 (6)0.125 (5)−0.028 (4)0.075 (4)0.015 (4)
O2B30.073 (3)0.057 (4)0.047 (3)−0.008 (3)0.027 (3)−0.005 (3)
O3B30.064 (4)0.083 (4)0.049 (3)0.014 (3)0.013 (3)−0.002 (3)
O4B30.079 (4)0.112 (5)0.068 (4)0.028 (4)0.010 (3)−0.032 (4)
O5B30.070 (4)0.107 (5)0.059 (4)−0.003 (4)0.027 (3)−0.011 (4)
C1A40.046 (5)0.064 (6)0.063 (5)−0.003 (5)0.010 (4)0.002 (5)
C2A40.061 (5)0.039 (6)0.052 (5)0.015 (4)0.010 (4)0.006 (4)
C3A40.099 (7)0.048 (6)0.043 (5)−0.022 (5)0.019 (5)−0.003 (4)
C4A40.086 (7)0.052 (6)0.067 (6)−0.002 (5)0.033 (5)−0.003 (5)
C5A40.079 (6)0.053 (6)0.067 (6)−0.018 (5)0.023 (5)−0.004 (5)
C6A40.051 (6)0.133 (10)0.121 (8)0.032 (6)0.027 (6)0.018 (7)
O2A40.095 (4)0.045 (4)0.066 (4)−0.016 (3)0.016 (3)0.020 (3)
O3A40.118 (5)0.056 (4)0.063 (4)−0.024 (4)0.000 (3)0.002 (3)
O4A40.188 (6)0.072 (4)0.083 (4)−0.001 (5)0.088 (4)−0.012 (4)
O5A40.063 (4)0.058 (4)0.049 (3)0.005 (3)0.010 (3)0.002 (3)
C1B40.072 (6)0.061 (6)0.057 (5)0.001 (5)0.007 (5)−0.012 (5)
C2B40.071 (6)0.032 (5)0.054 (5)0.009 (5)0.020 (4)0.005 (4)
C3B40.059 (5)0.062 (6)0.041 (5)−0.003 (5)0.025 (4)−0.013 (4)
C4B40.075 (6)0.036 (5)0.052 (5)−0.004 (5)0.014 (5)−0.004 (4)
C5B40.064 (6)0.032 (6)0.089 (7)−0.001 (5)0.013 (5)0.004 (5)
C6B40.136 (9)0.085 (8)0.105 (8)−0.009 (7)0.056 (7)0.021 (6)
C7B40.099 (9)0.121 (10)0.138 (9)−0.031 (8)−0.036 (7)−0.034 (8)
O7B40.120 (5)0.069 (4)0.067 (4)−0.012 (4)−0.004 (4)−0.016 (4)
O2B40.091 (4)0.033 (3)0.050 (3)−0.012 (3)0.019 (3)−0.002 (3)
O3B40.075 (4)0.049 (4)0.071 (4)−0.002 (3)0.023 (3)−0.012 (3)
O4B40.086 (4)0.049 (4)0.090 (4)0.001 (3)0.028 (4)0.009 (3)
O5B40.066 (4)0.074 (5)0.084 (4)0.000 (3)0.025 (3)−0.017 (4)
O10.243 (9)0.089 (6)0.114 (6)−0.010 (6)0.057 (6)−0.003 (5)
O20.191 (7)0.070 (5)0.085 (4)0.014 (5)0.037 (5)−0.014 (4)
O30.223 (8)0.116 (6)0.060 (4)0.022 (6)0.047 (4)0.003 (4)
O40.185 (10)0.263 (13)0.283 (13)−0.015 (10)0.038 (9)0.057 (12)
C1A1—O2B11.403 (8)C2A3—O2A31.438 (8)
C1A1—O5A11.420 (8)C2A3—C3A31.499 (10)
C1A1—C2A11.499 (10)C2A3—H2A51.0000
C1A1—H1A11.0000C3A3—O3A31.413 (9)
C2A1—O2A11.429 (8)C3A3—C4A31.478 (9)
C2A1—C3A11.472 (11)C3A3—H3A51.0000
C2A1—H2A11.0000C4A3—O4A31.449 (9)
C3A1—O3A11.424 (9)C4A3—C5A31.520 (10)
C3A1—C4A11.521 (11)C4A3—H4A51.0000
C3A1—H3A11.0000C5A3—O5A31.421 (9)
C4A1—O4A11.427 (9)C5A3—C6A31.512 (10)
C4A1—C5A11.512 (11)C5A3—H5A31.0000
C4A1—H4A11.0000C6A3—H6A70.9800
C5A1—O5A11.435 (9)C6A3—H6A80.9800
C5A1—C6A11.497 (10)C6A3—H6A90.9800
C5A1—H5A11.0000O2A3—H2A60.8400
C6A1—H6A10.9800O3A3—H3A60.8400
C6A1—H6A20.9800O4A3—H4A60.8400
C6A1—H6A30.9800C1B3—O5B31.379 (10)
O2A1—H2A20.8400C1B3—O7B31.419 (10)
O3A1—H3A20.8400C1B3—C2B31.521 (10)
O4A1—H4A20.8400C1B3—H1B31.0000
C1B1—O7B11.395 (10)C2B3—O2B31.470 (8)
C1B1—O5B11.396 (10)C2B3—C3B31.509 (10)
C1B1—C2B11.549 (10)C2B3—H2B31.0000
C1B1—H1B11.0000C3B3—O3B31.410 (8)
C2B1—O2B11.450 (8)C3B3—C4B31.480 (10)
C2B1—C3B11.498 (10)C3B3—H3B51.0000
C2B1—H2B11.0000C4B3—O4B31.432 (8)
C3B1—O3B11.405 (8)C4B3—C5B31.497 (10)
C3B1—C4B11.506 (10)C4B3—H4B51.0000
C3B1—H3B11.0000C5B3—O5B31.452 (9)
C4B1—O4B11.439 (8)C5B3—C6B31.518 (12)
C4B1—C5B11.537 (10)C5B3—H5B31.0000
C4B1—H4B11.0000C6B3—H6B70.9800
C5B1—O5B11.416 (9)C6B3—H6B80.9800
C5B1—C6B11.531 (11)C6B3—H6B90.9800
C5B1—H5B11.0000C7B3—O7B31.423 (11)
C6B1—H6B10.9800C7B3—H7B70.9800
C6B1—H6B20.9800C7B3—H7B80.9800
C6B1—H6B30.9800C7B3—H7B90.9800
C7B1—O7B11.383 (10)O3B3—H3B60.8400
C7B1—H7B10.9800O4B3—H4B60.8400
C7B1—H7B20.9800C1A4—O5A41.388 (8)
C7B1—H7B30.9800C1A4—O2B41.432 (9)
O3B1—H3B20.8400C1A4—C2A41.505 (10)
O4B1—H4B20.8400C1A4—H1A41.0000
C1A2—O5A21.400 (9)C2A4—O2A41.421 (9)
C1A2—O2B21.420 (8)C2A4—C3A41.536 (10)
C1A2—C2A21.526 (10)C2A4—H2A71.0000
C1A2—H1A21.0000C3A4—O3A41.401 (9)
C2A2—O2A21.428 (9)C3A4—C4A41.524 (11)
C2A2—C3A21.490 (10)C3A4—H3A71.0000
C2A2—H2A31.0000C4A4—O4A41.407 (9)
C3A2—O3A21.409 (8)C4A4—C5A41.511 (11)
C3A2—C4A21.503 (10)C4A4—H4A71.0000
C3A2—H3A31.0000C5A4—O5A41.421 (9)
C4A2—O4A21.418 (8)C5A4—C6A41.543 (11)
C4A2—C5A21.506 (10)C5A4—H5A41.0000
C4A2—H4A31.0000C6A4—H6AX0.9800
C5A2—O5A21.426 (9)C6A4—H6AY0.9800
C5A2—C6A21.514 (11)C6A4—H6AZ0.9800
C5A2—H5A21.0000O2A4—H2A80.8400
C6A2—H6A40.9800O3A4—H3A80.8400
C6A2—H6A50.9800O4A4—H4A80.8400
C6A2—H6A60.9800C1B4—O7B41.383 (9)
O2A2—H2A40.8400C1B4—O5B41.427 (9)
O3A2—H3A40.8400C1B4—C2B41.512 (10)
O4A2—H4A40.8400C1B4—H1B41.0000
C1B2—O7B21.405 (8)C2B4—O2B41.421 (8)
C1B2—O5B21.430 (9)C2B4—C3B41.491 (10)
C1B2—C2B21.546 (10)C2B4—H2B41.0000
C1B2—H1B21.0000C3B4—O3B41.415 (8)
C2B2—O2B21.431 (8)C3B4—C4B41.467 (10)
C2B2—C3B21.465 (10)C3B4—H3B71.0000
C2B2—H2B21.0000C4B4—O4B41.423 (8)
C3B2—O3B21.443 (8)C4B4—C5B41.501 (10)
C3B2—C4B21.477 (9)C4B4—H4B71.0000
C3B2—H3B31.0000C5B4—O5B41.452 (9)
C4B2—O4B21.428 (8)C5B4—C6B41.505 (12)
C4B2—C5B21.517 (10)C5B4—H5B41.0000
C4B2—H4B31.0000C6B4—H6BX0.9800
C5B2—O5B21.428 (10)C6B4—H6BY0.9800
C5B2—C6B21.484 (11)C6B4—H6BZ0.9800
C5B2—H5B21.0000C7B4—O7B41.451 (10)
C6B2—H6B40.9800C7B4—H7BX0.9800
C6B2—H6B50.9800C7B4—H7BY0.9800
C6B2—H6B60.9800C7B4—H7BZ0.9800
C7B2—O7B21.402 (9)O3B4—H3B80.8400
C7B2—H7B40.9800O4B4—H4B80.8400
C7B2—H7B50.9800O1—H110.873 (14)
C7B2—H7B60.9800O1—H120.860 (14)
O3B2—H3B40.8400O2—H210.850 (14)
O4B2—H4B40.8400O2—H220.849 (14)
C1A3—O5A31.409 (8)O3—H310.849 (14)
C1A3—O2B31.417 (8)O3—H320.847 (14)
C1A3—C2A31.485 (10)O4—H410.850 (14)
C1A3—H1A31.0000O4—H420.854 (14)
O2B1—C1A1—O5A1112.4 (6)O2B3—C1A3—C2A3107.3 (6)
O2B1—C1A1—C2A1109.3 (6)O5A3—C1A3—H1A3108.7
O5A1—C1A1—C2A1112.1 (6)O2B3—C1A3—H1A3108.7
O2B1—C1A1—H1A1107.6C2A3—C1A3—H1A3108.7
O5A1—C1A1—H1A1107.6O2A3—C2A3—C1A3107.2 (6)
C2A1—C1A1—H1A1107.6O2A3—C2A3—C3A3109.1 (6)
O2A1—C2A1—C3A1108.8 (6)C1A3—C2A3—C3A3113.2 (7)
O2A1—C2A1—C1A1109.9 (7)O2A3—C2A3—H2A5109.1
C3A1—C2A1—C1A1110.8 (7)C1A3—C2A3—H2A5109.1
O2A1—C2A1—H2A1109.1C3A3—C2A3—H2A5109.1
C3A1—C2A1—H2A1109.1O3A3—C3A3—C4A3110.6 (6)
C1A1—C2A1—H2A1109.1O3A3—C3A3—C2A3110.9 (6)
O3A1—C3A1—C2A1109.9 (7)C4A3—C3A3—C2A3111.2 (7)
O3A1—C3A1—C4A1110.2 (7)O3A3—C3A3—H3A5108.0
C2A1—C3A1—C4A1112.5 (7)C4A3—C3A3—H3A5108.0
O3A1—C3A1—H3A1108.0C2A3—C3A3—H3A5108.0
C2A1—C3A1—H3A1108.0O4A3—C4A3—C3A3111.6 (7)
C4A1—C3A1—H3A1108.0O4A3—C4A3—C5A3107.7 (6)
O4A1—C4A1—C5A1111.0 (7)C3A3—C4A3—C5A3112.1 (6)
O4A1—C4A1—C3A1110.3 (7)O4A3—C4A3—H4A5108.4
C5A1—C4A1—C3A1109.0 (7)C3A3—C4A3—H4A5108.4
O4A1—C4A1—H4A1108.8C5A3—C4A3—H4A5108.4
C5A1—C4A1—H4A1108.8O5A3—C5A3—C6A3105.6 (7)
C3A1—C4A1—H4A1108.8O5A3—C5A3—C4A3111.2 (6)
O5A1—C5A1—C6A1107.0 (7)C6A3—C5A3—C4A3117.8 (7)
O5A1—C5A1—C4A1109.5 (6)O5A3—C5A3—H5A3107.3
C6A1—C5A1—C4A1113.8 (7)C6A3—C5A3—H5A3107.3
O5A1—C5A1—H5A1108.8C4A3—C5A3—H5A3107.3
C6A1—C5A1—H5A1108.8C5A3—C6A3—H6A7109.5
C4A1—C5A1—H5A1108.8C5A3—C6A3—H6A8109.5
C5A1—C6A1—H6A1109.5H6A7—C6A3—H6A8109.5
C5A1—C6A1—H6A2109.5C5A3—C6A3—H6A9109.5
H6A1—C6A1—H6A2109.5H6A7—C6A3—H6A9109.5
C5A1—C6A1—H6A3109.5H6A8—C6A3—H6A9109.5
H6A1—C6A1—H6A3109.5C2A3—O2A3—H2A6109.5
H6A2—C6A1—H6A3109.5C3A3—O3A3—H3A6109.5
C2A1—O2A1—H2A2109.5C4A3—O4A3—H4A6109.5
C3A1—O3A1—H3A2109.5C1A3—O5A3—C5A3114.8 (6)
C4A1—O4A1—H4A2109.5O5B3—C1B3—O7B3111.6 (7)
C1A1—O5A1—C5A1112.7 (6)O5B3—C1B3—C2B3113.2 (7)
O7B1—C1B1—O5B1113.1 (7)O7B3—C1B3—C2B3104.2 (7)
O7B1—C1B1—C2B1105.2 (7)O5B3—C1B3—H1B3109.2
O5B1—C1B1—C2B1112.5 (7)O7B3—C1B3—H1B3109.2
O7B1—C1B1—H1B1108.6C2B3—C1B3—H1B3109.2
O5B1—C1B1—H1B1108.6O2B3—C2B3—C3B3106.8 (6)
C2B1—C1B1—H1B1108.6O2B3—C2B3—C1B3108.4 (6)
O2B1—C2B1—C3B1106.4 (6)C3B3—C2B3—C1B3114.0 (7)
O2B1—C2B1—C1B1108.8 (6)O2B3—C2B3—H2B3109.2
C3B1—C2B1—C1B1112.2 (6)C3B3—C2B3—H2B3109.2
O2B1—C2B1—H2B1109.8C1B3—C2B3—H2B3109.2
C3B1—C2B1—H2B1109.8O3B3—C3B3—C4B3112.4 (7)
C1B1—C2B1—H2B1109.8O3B3—C3B3—C2B3113.6 (6)
O3B1—C3B1—C2B1111.6 (6)C4B3—C3B3—C2B3111.8 (6)
O3B1—C3B1—C4B1110.9 (6)O3B3—C3B3—H3B5106.1
C2B1—C3B1—C4B1111.6 (6)C4B3—C3B3—H3B5106.1
O3B1—C3B1—H3B1107.5C2B3—C3B3—H3B5106.1
C2B1—C3B1—H3B1107.5O4B3—C4B3—C3B3110.3 (6)
C4B1—C3B1—H3B1107.5O4B3—C4B3—C5B3107.8 (6)
O4B1—C4B1—C3B1108.8 (6)C3B3—C4B3—C5B3111.3 (7)
O4B1—C4B1—C5B1110.3 (6)O4B3—C4B3—H4B5109.1
C3B1—C4B1—C5B1109.7 (7)C3B3—C4B3—H4B5109.1
O4B1—C4B1—H4B1109.4C5B3—C4B3—H4B5109.1
C3B1—C4B1—H4B1109.4O5B3—C5B3—C4B3107.7 (6)
C5B1—C4B1—H4B1109.4O5B3—C5B3—C6B3109.0 (7)
O5B1—C5B1—C6B1109.4 (7)C4B3—C5B3—C6B3114.5 (8)
O5B1—C5B1—C4B1107.9 (6)O5B3—C5B3—H5B3108.5
C6B1—C5B1—C4B1111.8 (7)C4B3—C5B3—H5B3108.5
O5B1—C5B1—H5B1109.3C6B3—C5B3—H5B3108.5
C6B1—C5B1—H5B1109.3C5B3—C6B3—H6B7109.5
C4B1—C5B1—H5B1109.3C5B3—C6B3—H6B8109.5
C5B1—C6B1—H6B1109.5H6B7—C6B3—H6B8109.5
C5B1—C6B1—H6B2109.5C5B3—C6B3—H6B9109.5
H6B1—C6B1—H6B2109.5H6B7—C6B3—H6B9109.5
C5B1—C6B1—H6B3109.5H6B8—C6B3—H6B9109.5
H6B1—C6B1—H6B3109.5O7B3—C7B3—H7B7109.5
H6B2—C6B1—H6B3109.5O7B3—C7B3—H7B8109.5
O7B1—C7B1—H7B1109.5H7B7—C7B3—H7B8109.5
O7B1—C7B1—H7B2109.5O7B3—C7B3—H7B9109.5
H7B1—C7B1—H7B2109.5H7B7—C7B3—H7B9109.5
O7B1—C7B1—H7B3109.5H7B8—C7B3—H7B9109.5
H7B1—C7B1—H7B3109.5C1B3—O7B3—C7B3111.1 (8)
H7B2—C7B1—H7B3109.5C1A3—O2B3—C2B3114.2 (6)
C7B1—O7B1—C1B1113.4 (8)C3B3—O3B3—H3B6109.5
C1A1—O2B1—C2B1113.9 (6)C4B3—O4B3—H4B6109.5
C3B1—O3B1—H3B2109.5C1B3—O5B3—C5B3115.1 (7)
C4B1—O4B1—H4B2109.5O5A4—C1A4—O2B4111.5 (6)
C1B1—O5B1—C5B1115.2 (7)O5A4—C1A4—C2A4112.6 (7)
O5A2—C1A2—O2B2111.8 (6)O2B4—C1A4—C2A4107.4 (6)
O5A2—C1A2—C2A2112.8 (6)O5A4—C1A4—H1A4108.4
O2B2—C1A2—C2A2105.6 (6)O2B4—C1A4—H1A4108.4
O5A2—C1A2—H1A2108.8C2A4—C1A4—H1A4108.4
O2B2—C1A2—H1A2108.8O2A4—C2A4—C1A4110.9 (6)
C2A2—C1A2—H1A2108.8O2A4—C2A4—C3A4111.0 (6)
O2A2—C2A2—C3A2110.5 (6)C1A4—C2A4—C3A4109.4 (7)
O2A2—C2A2—C1A2109.3 (6)O2A4—C2A4—H2A7108.5
C3A2—C2A2—C1A2109.1 (6)C1A4—C2A4—H2A7108.5
O2A2—C2A2—H2A3109.3C3A4—C2A4—H2A7108.5
C3A2—C2A2—H2A3109.3O3A4—C3A4—C4A4113.0 (7)
C1A2—C2A2—H2A3109.3O3A4—C3A4—C2A4109.0 (7)
O3A2—C3A2—C2A2108.0 (6)C4A4—C3A4—C2A4112.2 (6)
O3A2—C3A2—C4A2112.7 (7)O3A4—C3A4—H3A7107.5
C2A2—C3A2—C4A2112.5 (7)C4A4—C3A4—H3A7107.5
O3A2—C3A2—H3A3107.8C2A4—C3A4—H3A7107.5
C2A2—C3A2—H3A3107.8O4A4—C4A4—C5A4109.8 (7)
C4A2—C3A2—H3A3107.8O4A4—C4A4—C3A4110.2 (7)
O4A2—C4A2—C3A2109.4 (7)C5A4—C4A4—C3A4109.4 (7)
O4A2—C4A2—C5A2110.9 (6)O4A4—C4A4—H4A7109.1
C3A2—C4A2—C5A2112.6 (7)C5A4—C4A4—H4A7109.1
O4A2—C4A2—H4A3107.9C3A4—C4A4—H4A7109.1
C3A2—C4A2—H4A3107.9O5A4—C5A4—C4A4112.2 (7)
C5A2—C4A2—H4A3107.9O5A4—C5A4—C6A4107.9 (7)
O5A2—C5A2—C4A2110.8 (6)C4A4—C5A4—C6A4110.1 (8)
O5A2—C5A2—C6A2106.8 (7)O5A4—C5A4—H5A4108.9
C4A2—C5A2—C6A2112.3 (8)C4A4—C5A4—H5A4108.9
O5A2—C5A2—H5A2109.0C6A4—C5A4—H5A4108.9
C4A2—C5A2—H5A2109.0C5A4—C6A4—H6AX109.5
C6A2—C5A2—H5A2109.0C5A4—C6A4—H6AY109.5
C5A2—C6A2—H6A4109.5H6AX—C6A4—H6AY109.5
C5A2—C6A2—H6A5109.5C5A4—C6A4—H6AZ109.5
H6A4—C6A2—H6A5109.5H6AX—C6A4—H6AZ109.5
C5A2—C6A2—H6A6109.5H6AY—C6A4—H6AZ109.5
H6A4—C6A2—H6A6109.5C2A4—O2A4—H2A8109.5
H6A5—C6A2—H6A6109.5C3A4—O3A4—H3A8109.5
C2A2—O2A2—H2A4109.5C4A4—O4A4—H4A8109.5
C3A2—O3A2—H3A4109.5C1A4—O5A4—C5A4113.4 (6)
C4A2—O4A2—H4A4109.5O7B4—C1B4—O5B4111.9 (7)
C1A2—O5A2—C5A2113.7 (6)O7B4—C1B4—C2B4109.2 (7)
O7B2—C1B2—O5B2111.0 (6)O5B4—C1B4—C2B4110.6 (6)
O7B2—C1B2—C2B2106.4 (6)O7B4—C1B4—H1B4108.4
O5B2—C1B2—C2B2110.1 (6)O5B4—C1B4—H1B4108.4
O7B2—C1B2—H1B2109.8C2B4—C1B4—H1B4108.4
O5B2—C1B2—H1B2109.8O2B4—C2B4—C3B4107.3 (6)
C2B2—C1B2—H1B2109.8O2B4—C2B4—C1B4109.7 (6)
O2B2—C2B2—C3B2108.7 (6)C3B4—C2B4—C1B4112.7 (7)
O2B2—C2B2—C1B2109.0 (6)O2B4—C2B4—H2B4109.0
C3B2—C2B2—C1B2111.8 (7)C3B4—C2B4—H2B4109.0
O2B2—C2B2—H2B2109.1C1B4—C2B4—H2B4109.0
C3B2—C2B2—H2B2109.1O3B4—C3B4—C4B4112.6 (6)
C1B2—C2B2—H2B2109.1O3B4—C3B4—C2B4111.3 (7)
O3B2—C3B2—C2B2109.3 (6)C4B4—C3B4—C2B4112.3 (7)
O3B2—C3B2—C4B2110.3 (6)O3B4—C3B4—H3B7106.7
C2B2—C3B2—C4B2112.7 (6)C4B4—C3B4—H3B7106.7
O3B2—C3B2—H3B3108.2C2B4—C3B4—H3B7106.7
C2B2—C3B2—H3B3108.2O4B4—C4B4—C3B4111.9 (7)
C4B2—C3B2—H3B3108.2O4B4—C4B4—C5B4107.7 (6)
O4B2—C4B2—C3B2109.8 (6)C3B4—C4B4—C5B4110.9 (7)
O4B2—C4B2—C5B2108.2 (7)O4B4—C4B4—H4B7108.8
C3B2—C4B2—C5B2108.7 (7)C3B4—C4B4—H4B7108.8
O4B2—C4B2—H4B3110.0C5B4—C4B4—H4B7108.8
C3B2—C4B2—H4B3110.0O5B4—C5B4—C4B4106.1 (6)
C5B2—C4B2—H4B3110.0O5B4—C5B4—C6B4106.2 (7)
O5B2—C5B2—C6B2108.0 (7)C4B4—C5B4—C6B4117.0 (8)
O5B2—C5B2—C4B2107.8 (7)O5B4—C5B4—H5B4109.1
C6B2—C5B2—C4B2114.7 (8)C4B4—C5B4—H5B4109.1
O5B2—C5B2—H5B2108.7C6B4—C5B4—H5B4109.1
C6B2—C5B2—H5B2108.7C5B4—C6B4—H6BX109.5
C4B2—C5B2—H5B2108.7C5B4—C6B4—H6BY109.5
C5B2—C6B2—H6B4109.5H6BX—C6B4—H6BY109.5
C5B2—C6B2—H6B5109.5C5B4—C6B4—H6BZ109.5
H6B4—C6B2—H6B5109.5H6BX—C6B4—H6BZ109.5
C5B2—C6B2—H6B6109.5H6BY—C6B4—H6BZ109.5
H6B4—C6B2—H6B6109.5O7B4—C7B4—H7BX109.5
H6B5—C6B2—H6B6109.5O7B4—C7B4—H7BY109.5
O7B2—C7B2—H7B4109.5H7BX—C7B4—H7BY109.5
O7B2—C7B2—H7B5109.5O7B4—C7B4—H7BZ109.5
H7B4—C7B2—H7B5109.5H7BX—C7B4—H7BZ109.5
O7B2—C7B2—H7B6109.5H7BY—C7B4—H7BZ109.5
H7B4—C7B2—H7B6109.5C1B4—O7B4—C7B4111.8 (7)
H7B5—C7B2—H7B6109.5C2B4—O2B4—C1A4116.2 (5)
C7B2—O7B2—C1B2111.4 (7)C3B4—O3B4—H3B8109.5
C1A2—O2B2—C2B2117.2 (6)C4B4—O4B4—H4B8109.5
C3B2—O3B2—H3B4109.5C1B4—O5B4—C5B4114.6 (6)
C4B2—O4B2—H4B4109.5H11—O1—H12102 (2)
C5B2—O5B2—C1B2116.3 (6)H21—O2—H22104 (2)
O5A3—C1A3—O2B3111.3 (6)H31—O3—H32105 (2)
O5A3—C1A3—C2A3112.0 (6)H41—O4—H42105 (2)
O2B1—C1A1—C2A1—O2A1−166.8 (6)O5A3—C1A3—C2A3—O2A369.4 (7)
O5A1—C1A1—C2A1—O2A167.9 (9)O2B3—C1A3—C2A3—O2A3−168.2 (5)
O2B1—C1A1—C2A1—C3A172.8 (8)O5A3—C1A3—C2A3—C3A3−51.0 (8)
O5A1—C1A1—C2A1—C3A1−52.4 (9)O2B3—C1A3—C2A3—C3A371.4 (7)
O2A1—C2A1—C3A1—O3A152.9 (9)O2A3—C2A3—C3A3—O3A353.3 (8)
C1A1—C2A1—C3A1—O3A1173.9 (7)C1A3—C2A3—C3A3—O3A3172.6 (6)
O2A1—C2A1—C3A1—C4A1−70.3 (8)O2A3—C2A3—C3A3—C4A3−70.2 (8)
C1A1—C2A1—C3A1—C4A150.7 (9)C1A3—C2A3—C3A3—C4A349.1 (8)
O3A1—C3A1—C4A1—O4A161.3 (8)O3A3—C3A3—C4A3—O4A366.1 (8)
C2A1—C3A1—C4A1—O4A1−175.6 (6)C2A3—C3A3—C4A3—O4A3−170.2 (6)
O3A1—C3A1—C4A1—C5A1−176.5 (7)O3A3—C3A3—C4A3—C5A3−173.0 (6)
C2A1—C3A1—C4A1—C5A1−53.4 (9)C2A3—C3A3—C4A3—C5A3−49.3 (9)
O4A1—C4A1—C5A1—O5A1178.6 (6)O4A3—C4A3—C5A3—O5A3175.3 (6)
C3A1—C4A1—C5A1—O5A156.8 (8)C3A3—C4A3—C5A3—O5A352.1 (9)
O4A1—C4A1—C5A1—C6A1−61.7 (10)O4A3—C4A3—C5A3—C6A3−62.7 (9)
C3A1—C4A1—C5A1—C6A1176.5 (7)C3A3—C4A3—C5A3—C6A3174.1 (8)
O2B1—C1A1—O5A1—C5A1−64.7 (7)O2B3—C1A3—O5A3—C5A3−65.1 (8)
C2A1—C1A1—O5A1—C5A158.8 (8)C2A3—C1A3—O5A3—C5A355.0 (8)
C6A1—C5A1—O5A1—C1A1175.0 (6)C6A3—C5A3—O5A3—C1A3175.9 (6)
C4A1—C5A1—O5A1—C1A1−61.2 (8)C4A3—C5A3—O5A3—C1A3−55.3 (8)
O7B1—C1B1—C2B1—O2B1−164.4 (6)O5B3—C1B3—C2B3—O2B377.3 (8)
O5B1—C1B1—C2B1—O2B172.1 (8)O7B3—C1B3—C2B3—O2B3−161.3 (6)
O7B1—C1B1—C2B1—C3B178.2 (8)O5B3—C1B3—C2B3—C3B3−41.5 (10)
O5B1—C1B1—C2B1—C3B1−45.4 (9)O7B3—C1B3—C2B3—C3B380.0 (9)
O2B1—C2B1—C3B1—O3B152.2 (8)O2B3—C2B3—C3B3—O3B350.5 (8)
C1B1—C2B1—C3B1—O3B1171.1 (6)C1B3—C2B3—C3B3—O3B3170.1 (7)
O2B1—C2B1—C3B1—C4B1−72.5 (7)O2B3—C2B3—C3B3—C4B3−78.1 (8)
C1B1—C2B1—C3B1—C4B146.3 (8)C1B3—C2B3—C3B3—C4B341.6 (9)
O3B1—C3B1—C4B1—O4B159.8 (7)O3B3—C3B3—C4B3—O4B359.3 (8)
C2B1—C3B1—C4B1—O4B1−175.1 (6)C2B3—C3B3—C4B3—O4B3−171.5 (6)
O3B1—C3B1—C4B1—C5B1−179.5 (6)O3B3—C3B3—C4B3—C5B3178.9 (6)
C2B1—C3B1—C4B1—C5B1−54.4 (8)C2B3—C3B3—C4B3—C5B3−51.9 (8)
O4B1—C4B1—C5B1—O5B1−179.8 (6)O4B3—C4B3—C5B3—O5B3−178.7 (7)
C3B1—C4B1—C5B1—O5B160.4 (8)C3B3—C4B3—C5B3—O5B360.2 (9)
O4B1—C4B1—C5B1—C6B1−59.4 (9)O4B3—C4B3—C5B3—C6B3−57.4 (9)
C3B1—C4B1—C5B1—C6B1−179.2 (7)C3B3—C4B3—C5B3—C6B3−178.5 (7)
O5B1—C1B1—O7B1—C7B1−71.8 (9)O5B3—C1B3—O7B3—C7B3−70.1 (9)
C2B1—C1B1—O7B1—C7B1165.1 (7)C2B3—C1B3—O7B3—C7B3167.3 (8)
O5A1—C1A1—O2B1—C2B1−78.6 (8)O5A3—C1A3—O2B3—C2B3−83.7 (7)
C2A1—C1A1—O2B1—C2B1156.3 (6)C2A3—C1A3—O2B3—C2B3153.5 (6)
C3B1—C2B1—O2B1—C1A1−151.5 (6)C3B3—C2B3—O2B3—C1A3−149.4 (6)
C1B1—C2B1—O2B1—C1A187.4 (7)C1B3—C2B3—O2B3—C1A387.4 (8)
O7B1—C1B1—O5B1—C5B1−63.7 (9)O7B3—C1B3—O5B3—C5B3−64.5 (9)
C2B1—C1B1—O5B1—C5B155.4 (8)C2B3—C1B3—O5B3—C5B352.7 (9)
C6B1—C5B1—O5B1—C1B1175.6 (6)C4B3—C5B3—O5B3—C1B3−61.9 (9)
C4B1—C5B1—O5B1—C1B1−62.6 (8)C6B3—C5B3—O5B3—C1B3173.3 (7)
O5A2—C1A2—C2A2—O2A266.6 (8)O5A4—C1A4—C2A4—O2A468.7 (8)
O2B2—C1A2—C2A2—O2A2−171.0 (6)O2B4—C1A4—C2A4—O2A4−168.2 (6)
O5A2—C1A2—C2A2—C3A2−54.3 (8)O5A4—C1A4—C2A4—C3A4−54.0 (8)
O2B2—C1A2—C2A2—C3A268.1 (8)O2B4—C1A4—C2A4—C3A469.1 (8)
O2A2—C2A2—C3A2—O3A254.3 (8)O2A4—C2A4—C3A4—O3A453.1 (8)
C1A2—C2A2—C3A2—O3A2174.5 (6)C1A4—C2A4—C3A4—O3A4175.8 (6)
O2A2—C2A2—C3A2—C4A2−70.7 (8)O2A4—C2A4—C3A4—C4A4−72.9 (8)
C1A2—C2A2—C3A2—C4A249.5 (9)C1A4—C2A4—C3A4—C4A449.8 (9)
O3A2—C3A2—C4A2—O4A264.1 (8)O3A4—C3A4—C4A4—O4A465.7 (9)
C2A2—C3A2—C4A2—O4A2−173.4 (7)C2A4—C3A4—C4A4—O4A4−170.6 (7)
O3A2—C3A2—C4A2—C5A2−172.1 (6)O3A4—C3A4—C4A4—C5A4−173.5 (6)
C2A2—C3A2—C4A2—C5A2−49.6 (9)C2A4—C3A4—C4A4—C5A4−49.8 (9)
O4A2—C4A2—C5A2—O5A2173.8 (6)O4A4—C4A4—C5A4—O5A4174.4 (7)
C3A2—C4A2—C5A2—O5A250.8 (9)C3A4—C4A4—C5A4—O5A453.3 (9)
O4A2—C4A2—C5A2—C6A2−66.9 (9)O4A4—C4A4—C5A4—C6A4−65.4 (9)
C3A2—C4A2—C5A2—C6A2170.1 (7)C3A4—C4A4—C5A4—C6A4173.5 (7)
O2B2—C1A2—O5A2—C5A2−59.7 (8)O2B4—C1A4—O5A4—C5A4−60.8 (8)
C2A2—C1A2—O5A2—C5A259.2 (8)C2A4—C1A4—O5A4—C5A460.0 (8)
C4A2—C5A2—O5A2—C1A2−56.3 (8)C4A4—C5A4—O5A4—C1A4−59.7 (9)
C6A2—C5A2—O5A2—C1A2−178.9 (7)C6A4—C5A4—O5A4—C1A4178.8 (7)
O7B2—C1B2—C2B2—O2B2−165.9 (6)O7B4—C1B4—C2B4—O2B4−163.3 (6)
O5B2—C1B2—C2B2—O2B273.8 (8)O5B4—C1B4—C2B4—O2B473.2 (8)
O7B2—C1B2—C2B2—C3B273.9 (8)O7B4—C1B4—C2B4—C3B477.2 (8)
O5B2—C1B2—C2B2—C3B2−46.4 (9)O5B4—C1B4—C2B4—C3B4−46.3 (9)
O2B2—C2B2—C3B2—O3B254.2 (7)O2B4—C2B4—C3B4—O3B453.5 (8)
C1B2—C2B2—C3B2—O3B2174.5 (6)C1B4—C2B4—C3B4—O3B4174.4 (6)
O2B2—C2B2—C3B2—C4B2−68.8 (8)O2B4—C2B4—C3B4—C4B4−73.7 (8)
C1B2—C2B2—C3B2—C4B251.6 (9)C1B4—C2B4—C3B4—C4B447.2 (9)
O3B2—C3B2—C4B2—O4B261.0 (8)O3B4—C3B4—C4B4—O4B457.9 (9)
C2B2—C3B2—C4B2—O4B2−176.5 (6)C2B4—C3B4—C4B4—O4B4−175.6 (6)
O3B2—C3B2—C4B2—C5B2179.2 (6)O3B4—C3B4—C4B4—C5B4178.2 (6)
C2B2—C3B2—C4B2—C5B2−58.4 (9)C2B4—C3B4—C4B4—C5B4−55.3 (9)
O4B2—C4B2—C5B2—O5B2179.1 (6)O4B4—C4B4—C5B4—O5B4−176.5 (6)
C3B2—C4B2—C5B2—O5B259.9 (8)C3B4—C4B4—C5B4—O5B460.8 (9)
O4B2—C4B2—C5B2—C6B2−60.5 (10)O4B4—C4B4—C5B4—C6B4−58.3 (9)
C3B2—C4B2—C5B2—C6B2−179.7 (8)C3B4—C4B4—C5B4—C6B4179.0 (7)
O5B2—C1B2—O7B2—C7B2−69.7 (8)O5B4—C1B4—O7B4—C7B4−69.1 (9)
C2B2—C1B2—O7B2—C7B2170.6 (7)C2B4—C1B4—O7B4—C7B4168.2 (7)
O5A2—C1A2—O2B2—C2B2−90.7 (7)C3B4—C2B4—O2B4—C1A4−150.0 (6)
C2A2—C1A2—O2B2—C2B2146.2 (6)C1B4—C2B4—O2B4—C1A487.2 (8)
C3B2—C2B2—O2B2—C1A2−153.8 (6)O5A4—C1A4—O2B4—C2B4−82.4 (8)
C1B2—C2B2—O2B2—C1A284.1 (7)C2A4—C1A4—O2B4—C2B4153.8 (6)
C6B2—C5B2—O5B2—C1B2174.9 (7)O7B4—C1B4—O5B4—C5B4−65.3 (8)
C4B2—C5B2—O5B2—C1B2−60.5 (9)C2B4—C1B4—O5B4—C5B456.6 (8)
O7B2—C1B2—O5B2—C5B2−64.2 (8)C4B4—C5B4—O5B4—C1B4−63.2 (8)
C2B2—C1B2—O5B2—C5B253.3 (9)C6B4—C5B4—O5B4—C1B4171.6 (7)
D—H···AD—HH···AD···AD—H···A
O2A1—H2A2···O20.841.962.770 (9)161
O3A1—H3A2···O4A20.842.593.366 (10)154
O3B1—H3B2···O3A3i0.841.952.766 (8)164
O4B1—H4B2···O1ii0.841.892.693 (10)158
O2A2—H2A4···O1iii0.842.042.834 (10)159
O3A2—H3A4···O3ii0.841.852.647 (9)159
O4A2—H4A4···O4A10.842.092.862 (8)152
O3B2—H3B4···O3A2iv0.842.062.710 (7)133
O4B2—H4B4···O20.842.202.952 (8)150
O2A3—H2A6···O4B1ii0.841.982.791 (8)161
O3A3—H3A6···O3ii0.841.922.741 (9)165
O4A3—H4A6···O4A40.842.132.731 (9)128
O3B3—H3B6···O2A1iii0.842.583.309 (8)146
O3B3—H3B6···O3A1iii0.842.132.855 (8)145
O4B3—H4B6···O2A1iii0.842.002.754 (9)149
C3A4—H3A7···O3A31.002.563.431 (10)146
O3A4—H3A8···O3B4i0.842.082.761 (8)138
O4A4—H4A8···O4A10.842.052.717 (9)136
O3B4—H3B8···O3B1ii0.842.022.843 (7)168
O4B4—H4B8···O2A4ii0.842.082.859 (8)155
O1—H12···O4B3iv0.86 (1)1.86 (2)2.718 (10)174 (7)
O2—H21···O4B4v0.85 (1)2.29 (4)3.030 (9)145 (6)
O2—H22···O5A3v0.85 (1)2.62 (2)3.461 (9)169 (5)
O3—H31···O3A4i0.85 (1)2.00 (4)2.695 (8)139 (5)
O3—H32···O40.85 (1)1.80 (3)2.582 (13)152 (7)
O4—H41···O7B10.85 (1)2.29 (3)3.037 (14)147 (5)
O4—H42···O7B3vi0.85 (1)2.26 (3)3.021 (14)148 (4)
  10 in total

1.  A conformational study of alpha-L-Rhap-(1----2)-alpha-L-Rhap-(1----OMe) by NMR nuclear Overhauser effect spectroscopy (NOESY) and molecular dynamics calculations.

Authors:  G Widmalm; R A Byrd; W Egan
Journal:  Carbohydr Res       Date:  1992-05-22       Impact factor: 2.104

2.  Structural studies of the O-antigenic polysaccharide from Escherichia coli O139.

Authors:  C Marie; A Weintraub; G Widmalm
Journal:  Eur J Biochem       Date:  1998-06-01

3.  O-Acetylation in the O-specific polysaccharide isolated from Shigella flexneri serotype 2a.

Authors:  Joanna Kubler-Kielb; Evgeny Vinogradov; Chiayung Chu; Rachel Schneerson
Journal:  Carbohydr Res       Date:  2006-11-07       Impact factor: 2.104

4.  Flexibility at a glycosidic linkage revealed by molecular dynamics, stochastic modeling, and (13)C NMR spin relaxation: conformational preferences of α-L-Rhap-α-(1 → 2)-α-L-Rhap-OMe in water and dimethyl sulfoxide solutions.

Authors:  Robert Pendrill; Olof Engström; Andrea Volpato; Mirco Zerbetto; Antonino Polimeno; Göran Widmalm
Journal:  Phys Chem Chem Phys       Date:  2016-01-28       Impact factor: 3.676

5.  SHELXT - integrated space-group and crystal-structure determination.

Authors:  George M Sheldrick
Journal:  Acta Crystallogr A Found Adv       Date:  2015-01-01       Impact factor: 2.290

6.  Crystal structure refinement with SHELXL.

Authors:  George M Sheldrick
Journal:  Acta Crystallogr C Struct Chem       Date:  2015-01-01       Impact factor: 1.172

7.  Use of intensity quotients and differences in absolute structure refinement.

Authors:  Simon Parsons; Howard D Flack; Trixie Wagner
Journal:  Acta Crystallogr B Struct Sci Cryst Eng Mater       Date:  2013-05-17

8.  Methyl α-l-rhamnosyl-(1→2)[α-l-rhamnosyl-(1→3)]-α-l-rhamnoside penta-hydrate: synchrotron study.

Authors:  Lars Eriksson; Göran Widmalm
Journal:  Acta Crystallogr Sect E Struct Rep Online       Date:  2012-06-27

9.  Structure validation in chemical crystallography.

Authors:  Anthony L Spek
Journal:  Acta Crystallogr D Biol Crystallogr       Date:  2009-01-20

10.  The Cambridge Structural Database.

Authors:  Colin R Groom; Ian J Bruno; Matthew P Lightfoot; Suzanna C Ward
Journal:  Acta Crystallogr B Struct Sci Cryst Eng Mater       Date:  2016-04-01
  10 in total

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