Phosphole-containing calixpyrroles, calixphyrins, and porphyrins: synthesis and coordination chemistry.

Porphyrins are large heterocyclic macrocycles that bind metals to form complexes such as heme and chlorophyll. Porphyrinogens are related macrocycles in which the meso-carbons, the carbon atoms connecting the pyrroles or the related five-atom heterocycles, are all or partially reduced to methylene, disrupting the pi-electron conjugation. Both porphyrins and porphyrinogens are important components of natural and synthetic systems, and they have completely different coordination behavior. Consequently, the coordination chemistry of the entire porphyrin family, including regular porphyrins, porphyrinogens, and their expanded analogs, has been extensively investigated. Core modification, namely, replacing one or more pyrrole rings with other heterocyclic or carbocyclic rings, is a highly promising approach for creating unprecedented coordination properties in the porphyrin family. The size, shape, charge, and binding ability of the core-modified porphyrin platforms are readily tunable by variation of the heterole subunits. Until recently, however, the only atoms that could be incorporated into the core were carbon and chalcogens (the oxygen family). Phosphole, the phosphorus isologue of pyrrole, is considered a nonaromatic heterole because of insufficient pi-conjugation between the cis-dienic pi-system and the lone electron pair of the phosphorus atom. As a consequence, phospholes behave not only as efficient pi-conjugative frameworks but also as ordinary phosphine ligands for transition metals. With this in mind, we started a research project on core-modified porphyrins in which the phosphole subunit plays a crucial role in providing characteristic coordination environments. In this Account, we describe our efforts to explore the utility of phosphole-containing porphyrins and porphyrinogens as macrocyclic, mixed-donor ligands. We have established convenient methods for the synthesis of calixpyrroles, calixphyrins, and porphyrins with P and either O or S substitutions, that is, P,X,N(2)-hybrids, as well as the phosphatripyrrane precursors. We also have investigated the effects of varying the combination of core heteroatoms (P, N, S, and O) on the coordination properties of the hybrid macrocycles. Our recent investigations have shown that (1) the P,S,N(2)-calixpyrroles behave as monophosphine ligands while maintaining the hosting functions that originate from the pyrrole subunits, (2) the P,X,N(2)-calixphyrins behave as neutral, monoanionic, or dianionic tetradentate ligands with electronic structures that vary widely depending on the combination of heterole subunits, and (3) the P,S,N(2)-porphyrin behaves as a redox-active pi-ligand for group 10 (the Ni family) metals, affording a novel class of core-modified isophlorin complexes. As a whole, the incorporation of the phosphole subunit into the macrocyclic framework provides unprecedented coordinating properties for the porphyrin family, affording exceptional synthetic control over the behavior of these important macrocycles.

[1]  Y. Matano,et al.  Zinc-Induced Fluorescence Enhancement of the 5,10-Porphodimethene-Type Thiophene-Containing Calixphyrins , 2010 .

[2]  Y. Matano,et al.  Design and Synthesis of Phosphole‐Based π Systems for Novel Organic Materials , 2009 .

[3]  H. Nakano,et al.  Redox-coupled complexation of 23-phospha-21-thiaporphyrin with group 10 metals: a convenient access to stable core-modified isophlorin-metal complexes. , 2008, Journal of the American Chemical Society.

[4]  S. Sakaki,et al.  Synthesis of thiophene-containing hybrid calixphyrins of the 5,10-porphodimethene type. , 2008, The Journal of organic chemistry.

[5]  Y. Matano,et al.  Synthesis, Structures, and Coordinating Properties of Phosphole-Containing Hybrid Calixpyrroles , 2008 .

[6]  M. Hissler,et al.  Coordination Chemistry of Phosphole Ligands Substituted with Pyridyl Moieties: From Catalysis to Nonlinear Optics and Supramolecular Assemblies , 2008 .

[7]  S. Sakaki,et al.  Syntheses, structures, and coordination chemistry of phosphole-containing hybrid calixphyrins: promising macrocyclic P,N2,X-mixed donor ligands for designing reactive transition-metal complexes. , 2008, Journal of the American Chemical Society.

[8]  H. Nakano,et al.  Monophosphaporphyrins: oxidative pi-extension at the peripherally fused carbocycle of the phosphaporphyrin ring. , 2008, Organic letters.

[9]  Hiren C. Mandalia,et al.  Chemistry of Calixpyrroles , 2007 .

[10]  P. Boyd,et al.  Diboryl and diboranyl porphyrin complexes: synthesis, structural motifs, and redox chemistry: diborenyl porphyrin or diboranyl isophlorin? , 2007, Chemistry.

[11]  F. Tham,et al.  Synthesis and X-ray Crystal Structure of a P-Confused Carbaporphyrinoid , 2007 .

[12]  T. Vaid,et al.  Reversible oxidation state change in germanium(tetraphenylporphyrin) induced by a dative ligand: aromatic GeII(TPP) and antiaromatic GeIV(TPP)(pyridine)2. , 2007, Journal of the American Chemical Society.

[13]  H. Nakano,et al.  Synthesis of a phosphorus-containing hybrid porphyrin. , 2006, Organic letters.

[14]  T. Baumgartner,et al.  Organophosphorus π-Conjugated Materials , 2006 .

[15]  S. Sakaki,et al.  Phosphorus-containing hybrid calixphyrins: promising mixed-donor ligands for visible and efficient palladium catalysts. , 2006, Journal of the American Chemical Society.

[16]  Y. Matano,et al.  A convenient method for the synthesis of 2,5-difunctionalized phospholes bearing ester groups. , 2006, Journal of Organic Chemistry.

[17]  Y. Matano,et al.  Phosphole-Containing Hybrid Calixpyrroles: New Multifunctional Macrocyclic Ligands for Platinum(II) Ions , 2006 .

[18]  Iti Gupta,et al.  Recent developments in heteroporphyrins and their analogues , 2006 .

[19]  L. Latos‐Grażyński,et al.  Core modified porphyrins – a macrocyclic platform for organometallic chemistry , 2005 .

[20]  M. Mikołajczyk,et al.  Stereochemically dynamic 2,2'-biphosphole ligands for asymmetric catalysis , 2005 .

[21]  T. Vaid,et al.  An antiaromatic porphyrin complex: tetraphenylporphyrinato(silicon)(L)2 (L=THF or pyridine). , 2005, Journal of the American Chemical Society.

[22]  M. Senge Nucleophilic substitution as a tool for the synthesis of unsymmetrical porphyrins. , 2005, Accounts of chemical research.

[23]  P. Bouř,et al.  Conformational transitions of calixphyrin derivatives monitored by temperature-dependent NMR spectroscopy. Ab initio interpretation of the spectra. , 2005, The journal of physical chemistry. A.

[24]  P. Bouř,et al.  Calix[4]phyrins. Effect of peripheral substituents on conformational mobility and structure within a series of related systems. , 2004, Journal of the American Chemical Society.

[25]  C. Floriani,et al.  Metalation and Metal-Assisted Modifications of the Porphyrinogen Skeleton Using meso-Octaalkylporphyrinogen , 2003 .

[26]  L. Latos‐Grażyński Core‐Modified Heteroanalogues of Porphyrins and Metalloporphyrins , 2003 .

[27]  M. Hissler,et al.  Linear organic π-conjugated systems featuring the heavy Group 14 and 15 elements , 2003 .

[28]  Philip A. Gale,et al.  Calixpyrroles: Novel Anion and Neutral Substrate Receptors , 2003 .

[29]  M. Nguyen,et al.  A density functional study of the ground state electronic structure of phosphorus–porphyrins , 2003 .

[30]  T. K. Chandrashekar,et al.  Core-modified expanded porphyrins: new generation organic materials. , 2003, Accounts of chemical research.

[31]  F. Mathey Phospha-organic chemistry: panorama and perspectives. , 2003, Angewandte Chemie.

[32]  A. Osuka,et al.  Confusion, inversion, and creation--a new spring from porphyrin chemistry. , 2002, Chemical communications.

[33]  D. Sukumaran,et al.  21-Telluraporphyrins. 1. Impact of 21,23-Heteroatom Interactions on Electrochemical Redox Potentials, 125Te NMR Spectra, and Absorption Spectra , 2002 .

[34]  Jae-Won Ka,et al.  Synthesis of expanded calix[n]pyrroles and their furan or thiophene analogues , 2001 .

[35]  J. Sessler,et al.  Calixphyrins. Hybrid macrocycles at the structural crossroads between porphyrins and calixpyrroles , 2001 .

[36]  P. Schleyer,et al.  Global and Local Aromaticity in Porphyrins: An Analysis Based on Molecular Geometries and Nucleus‐Independent Chemical Shifts , 1998 .

[37]  F. Laporte,et al.  The Use of a Ten‐Membered Tetraphosphole Macrocycle to Increase the Lifetime of a Palladium Catalyst , 1997 .

[38]  A. Balch,et al.  Nickel complexes of 21-oxaporphyrin and 21, 23-dioxaporphyrin. , 1997, Chemistry.

[39]  C.‐H. Lee,et al.  Facile Syntheses of Modified Tripyrranes (cf. (III)) and Their Application to the Syntheses of Regioisomerically Pure Porphyrin Derivatives , 1996 .

[40]  Philip A. Gale,et al.  Calix[4]pyrroles:  Old Yet New Anion-Binding Agents , 1996 .

[41]  F. Mathey The organic chemistry of phospholes , 1988 .

[42]  D. Rabinovich,et al.  Synthesis of new tetraphenylporphyrin molecules containing heteroatoms other than nitrogen. III. Tetraphenyl-21-tellura-23-thiaporphyrin: an internally-bridged porphyrin , 1978 .

[43]  A. Ulman,et al.  Synthesis of new tetraphenylporphyrin molecules containing heteroatoms other than nitrogen. I. Tetraphenyl-21,23-dithiaporphyrin. , 1975, Journal of the American Chemical Society.

[44]  Kevin M. Smith,et al.  Porphyrins and metalloporphyrins. , 1975 .

[45]  G. Zon,et al.  Barriers to pyramidal inversion at phosphorus in phospholes, phosphindoles, and dibenzophospholes , 1971 .

[46]  R. Grigg,et al.  Synthesis of porphin analogues containing furan and/or thiophen rings , 1971 .