171192-59-9

Upstream product

• 102653-36-1 3-bromonaphthalene-2,7-diol 
• 100-44-7 benzyl chloride 
• 171192-57-7 6-bromo-7-(methoxymethoxy)naphthalen-2-ol 
• 171192-58-8 6-(benzyloxy)-2-bromo-3-(methoxymethoxy)naphthalene 

Downstream Products

• 118494-97-6 (R)-7,7-bis(benzyloxy)-2,2'-dihydroxy-1,1'-binaphthyl 
• 1257231-23-4 2-acetoxy-7-benzyloxy-3-bromonaphthalene 
• 171192-51-1 7,7'-Bis-benzyloxy-3,3'-dibromo-[1,1']binaphthalenyl-2,2'-diol 

Relevant academic research and scientific papers

Nicholas reactions in the construction of cyclohepta[ de ]naphthalenes and cyclohepta[de]naphthalenones. The total synthesis of microstegiol

The application of the Nicholas reaction chemistry of 2,7-dioxygenated naphthalenes in the synthesis of cyclohepta[de]napthalenes and in the synthesis of (±)-microstegiol (1) is presented. The substitution profile of Nicholas monosubstitution (predominantly C-1) and disubstitution reactions (predominantly 1,6-) on 2,7-dioxygenated napthalenes is reported. Application of a 1,8-dicondensation product and selected C-1 monocondensation products to the construction of cyclohepta[de]naphthalenes by way of ring closing metathesis and intramolecular Friedel-Crafts reactions, respectively, is described. Deprotection of the C-7 oxygen function to the corresponding naphthol allows tautomerization to cyclohepta[de]naphthalene-1-ones upon seven-membered-ring closure in most cases, and replacement of the C-2 oxygen function in the naphthalene by a methyl group ultimately allows the synthesis of (±)-microstegiol.

Molecular recognition of pyranosides by a family of trimeric, 1,1'- binaphthalene-derived cyclophane receptors

The synthesis and carbohydrate-recognition properties of a new family of optically active cyclophane receptors, 1-3, in which three 1,1'- binaphthalene-2,2'-diol spacers are interconnected by three buta-1,3- diynediyl linkers, are described. The macrocycles all contain highly preorganized cavities lined with six convergent OH groups for H-bonding and complementary in size and shape to monosaccharides. Compounds 1-3 differ by the functionality attached to the major groove of the 1,1'-binaphthalene- 2,2'-diol spacers. The major grooves of the spacers in 2 are unsubstituted, whereas those in 1 bear benzyloxy (BnO) groups in the 7,7'-positions and those in 3 2-phenylethyl groups in the 6,6'-positions. The preparation of the more planar, D3-symmetrical receptors (R,R,R)-1 (Schemes 1 and 2), (S,S,S)- 1 (Scheme 4), (S,S,S)-2 (Scheme 5), and (S,S,S)-3 (Scheme 8) involved as key step the Glaser-Hay cyclotrimerization of the corresponding OH-protected 3,3'-diethynyl-1-1'-binaphthalene-2,2'-diol precursors, which yielded tetrameric and pentameric macrocycles in addition to the desired trimeric compounds. The synthesis of the less planar, C2-symmetrical receptors (R,R,S)-2 (Scheme 6) and (S,S,R)-3 (Scheme 9) proceeded via two Glaser-Hay coupling steps. First, two monomeric precursors of identical configuration were oxidatively coupled to give a dimeric intermediate which was then subjected to macrocyclization with a third monomeric 1,1'-binaphthalene precursor of opposite configuration. The 3,3'-dialkynylation of the OH- protected 1,1'-binaphthalene-2,2'-diol precursors for the macrocyclizations was either performed by Stille (Scheme 1) or by Sonogashira (Schemes 4, 5, and 8) cross-coupling reactions. The flat D3-symmetrical receptors (R,R,R)- 1 and (S,S,S)-1 formed 1:1 cavity inclusion complexes with octyl 1-O- pyranosides in CDCl3 (300 K) with moderate stability (ΔG0 ca. -3 kcal mol-1) as well as moderate diastereo(Δ(ΔG0) up to 0.7 kcal mol-1) and enantioselectivity (Δ(ΔG0) =0.4 kcal mol-1) (Table 1). Stoichiometric 1:1 complexation by (S,S,S)-2 and (S,S,S)-3 could not be investigated by 1H- NMR binding titrations, due to very strong signal broadening. This broadening of the 1H-NMR resonances is presumably indicative of higher-order associations, in which the planar macrocycles sandwich the carbohydrate guests. The less planar C2-symmetrical receptor (S,S,R)-3 formed stable 1:1 complexes with binding free enthalpies of up to ΔG0 = - 5.0 kcal mol-1 (Table 2). With diastereoselectivities up to Δ(ΔG0) = 1.3 kcal mol-1 and enantioselectivities of Δ(ΔG0)= 0.9 kcal mol-1, (S,S,R)-3 is among the most selective artificial carbohydrate receptors known.

Eine neue Klasse chiraler, von 1,1'-Binaphthyl abgeleiteter Cyclophan-Rezeptoren: Komplexierung von Pyranosiden

Stichworte: Biaryle, Cyclophane, Kohlenhydrate, Molekulare Erkennung, Wasserstoffbruecken