Lithium Naphthalenide

Biographical Sketches

Introduction

During the last three decades, the use of lithium naphthalenide (LN) as a reductant in organic synthesis has increased considerably. It has been used for the reductive cleavage of benzyl ethers, [¹] N,N,N′,N′-tetramethylphosphorodiamidates, [²] and chlorinated aryloxyalkanoic acids. [³] It was found to be a useful reagent for the removal of sulfide and sulfone. [4] In addition, LN-induced reductive ­decyanation, [5] alkylation, [6] and dehalogenation [7] are also readily accomplished.

Lithium naphthalenide can be dissolved in ether, benzene, and tetrahydrofuran, and can be stored in solution up to several days. But it must be protected from air and moisture and can react with protic solvents and tetrahydrofuran at elevated temperatures. [8] It can be conveniently prepared as a stable stock solution by mixing equal parts of freshly cut lithium metal and naphthalene in tetrahydrofuran at room temperature. [9]

Abstracts

(A) Reductive Alkylations: Tsao and co-workers reported that LN could induce reductive alkyl­ation/addition reactions of aryl-, pyridyl-, and 2-thienyl-substituted dialkylacetonitriles. Upon treatment with LN in THF, both aryl and pyridyl precursors could undergo the reductive decyanation smoothly, and the in situ generated carbanions could be readily trapped by alkyl halides, ketones, aldehydes, or even oxygen to afford a wide range of highly substituted aromatic and heteroaromatic derivatives. [¹0] Furthermore, the phosphono groups could also be easily removed by reduction with LN and in situ generated enolates could be readily trapped with a variety of alkylating agents to allow for the installation of an alkyl group to the quaternary carbon centers. [¹¹]
(B) Reductive α-Selenenylation of α,α-Dialkyl-α-cyanoacetates: Ko and co-workers have found that α,α-dialkyl-α-cyanoacetates were readily reduced with LN to give the corresponding ester ­enolates, and the ester enolates could be readily trapped by phenyl­selenenyl bromide to obtain various highly substituted α-(phenyl­selanyl)acetates. [¹²]
(C) One-Pot Conversion of α-Cyanoacetates into α,β-Unsaturated Esters: Zhu and co-workers have developed a highly efficient and completely regiocontrolled procedure for the synthesis of α-phenylseleno ketones starting from readily available α-cyano ketones making use of the LN-induced reductive selenenylation. Moreover, α-phenylseleno thus formed without isolation upon subsequent treatment with hydrogen peroxide and acetic acid, could be further converted into the corresponding α,β-unsaturated ketones with high regioselectivity. [¹³]
(D) Reductive Cleavage of α,β-Epoxy Ketones: LN is also used as a mild and efficient reagent for the reductive of α,β-epoxy ketones to give the corresponding β-hydroxy ketones. [¹4]
(E) Reductive Elimination of Epoxy Mesylates: Wu et al. have found that LN can serve as a mild reducing agent for reductive elimination of epoxy mesylates into the transpositioned allylic alcohol. [¹5] The reaction conditions displayed a high tolerance for the substrate bearing a phenyl group.
(F) Reductive Double Cyclization of Bis(arylcarbonyl)diphenylacetylenes: In addition to the above cases, LN can also be applied as a reductant for intramolecular reductive double cyclization of bis(arylcarbonyl)diphenylacetylenes. The reaction proceeded in THF at room temperature to produce the trans and cis isomers of hydroxymethy­lene-bridged stilbenes and dibenzo[a,e]pentalenes. [¹6]

References

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References

• 1a Liu HJ. Yip J. Shia KS. Tetrahedron Lett.  1997,  38:  2253 
  Google Scholar
• 1b Khare NK. Reynolds RC. Maddry JA. Indian J. Chem.  2008,  47B, 1748 
  Google Scholar
• 2 Liu HJ. Shang X. Tetrahedron Lett.  1998,  39:  36 
  Google Scholar
• 3 Azzena U. Pittalis M. Tetrahedron  2011,  67:  3360 
  Google Scholar
• 4a Huang PQ. Synlett  2006,  1133 
  Google Scholar
• 4b Chen W. Zheng X. Ruan YP. Huang PQ. Heterocycles  2009,  79:  681 
  Google Scholar
• 4c Denmark SE. Kobayashi T. Regens CS. Tetrahedron  2010,  66:  4745 
  Google Scholar
• 4d Hirai S. Nakada M. Tetrahedron Lett.  2010,  51:  5076 
  Google Scholar
• 4e Hirai S. Nakada M. Tetrahedron  2011,  67:  518 
  Google Scholar
• 5 Amancha PK. Liu HJ. Ly TW. Shia KS. Eur. J. Org. Chem.  2010,  3473 
  Google Scholar
• 6a Chu KC. Liu HJ. Zhu JL. Synlett  2010,  3061 
  Google Scholar
• 6b Amancha PK. Lai YC. Chen IC. Liu HJ. Zhu JL. Tetrahedron  2010,  66:  871 
  Google Scholar
• 6d Zhu JL. Huang PW. You RY. Lee FY. Tsao SW. Chen IC. Synthesis  2011,  715 
  Google Scholar
• 6e Chin CL. Liao CF. Liu HJ. Wong YC. Hsieh MT. Amancha PK. Chang CP. Shia KS. Org. Biomol. Chem.  2011,  9:  4778 
  Google Scholar
• 7 Watanabe H. Takeuchi K. Nakajima K. Nagai Y. Goto M. Chem. Lett.  1988,  1343 
  Google Scholar
• 8 Fujita T. Suga K. Watanabe S. Synthesis  1972,  630 
  Google Scholar
• 9 Hilmey DG. Paquette LA. Org. Synth.  2007,  84:  156 
  Google Scholar
• 10 Tsao JP. Tsai TY. Chen IC. Liu HJ. Zhu JL. Tsao SW. Synthesis  2010,  4242 
  Google Scholar
• 11 Liao CC. Zhu JL. J. Org. Chem.  2009,  74:  7873 
  Google Scholar
• 12 Ko YC. Zhu JL. Synthesis  2007,  3659 
  Google Scholar
• 13 Zhu JL. Ko YC. Kuo CW. Shia KS. Synlett  2007,  1274 
  Google Scholar
• 14 Jankowska R. Mhehe GL. Liu HJ. Chem. Commun.  1999,  1581 
  Google Scholar
• 15 Wu YK. Liu HJ. Zhu JL. Synlett  2008,  621 
  Google Scholar
• 16 Zhang HY. Karasawa T. Yamada H. Wakamiya A. Yamaguchi S. Org. Lett.  2009,  11:  3076 
  Google Scholar