Polypyrrolic systems : anion binding, photophysical properties, and electron transfer / Anion binding, photophysical properties, and electron transfer

Karnas, Elizabeth Theresa

15 February 2012

Anion Binding has recently emerged as an important field of study due to the role these small inorganic species play in a plethora of biological processes. Chapter 1 of this thesis describes the biological relevance and scientific justifications for studying the ability of synthetic molecules to transport or extract anions under interfacial conditions. This chapter also serves to underscore the need to study both the thermodynamics and kinetics of anion binding as achieved using synthetic receptors. Methods for determining the thermodynamics of ion recognition are well-developed, and many equilibrium analyses of supramolecular binding events have been reported; however, the kinetics of such interactions are often neglected. Chapter 2 details the author's efforts to address this deficiency with respect to anion-binding and reports progress towards quantitative kinetic analyses of the interaction between cyclo[8]pyrrole (C8), an expanded porphyrin, and two test anions. It has been determined that stopped-flow analysis can provide on and off-rates, as well as activation parameters not accessible through thermodynamic means. Initial flash photolysis kinetic studies have also revealed that C8 has the potential to act as a photosensitizing agent through electron donation. This work is presented in Chapter 3, wherein the author discusses the construction of novel donor-acceptor dyads based on C8. As detailed in this chapter, time-resolved optical analyses have confirmed that photoinduced electron transfer occurs under conditions of photoexcitation and that the lifetime of the charge separated state is approximately 300 [mu]s. Finally, Chapter 4 describes a comprehensive set of spectroscopic work conducted by the author involving porphyrin and porphycenes that have a RuCp* (Cp*: pentamethylcyclopentadienyl) fragment either coordinated to the central porphyrinic core or directly attached to the "[pi]-face" of the macrocycle. These systems display unique intramolecular electron transfer properties that are ascribed to the metallated-porphyrin core acting as an electron acceptor, as opposed to a donor as is normally observed with porphyrins. / text

Anion binding

Expanded porphyrins

Electron transfer

Expanded porphyrins as experimental anticancer agents and MRI contrast agents

Preihs, Christian

04 March 2014

Texaphyrins represent the vanguard of experimental anticancer drugs and also symbolize a well-known example of expanded porphyrins, a class of oligopyrrolic macrocycles with tumor localization properties and powerful metal chelating properties. Chapter 1 of this thesis describes the unique structural characteristics of this complex synthetic molecule along with the biological relevance and scientific justifications for studying its anticancer properties and powerful MRI contrast ability. This Chapter also serves to underscore the need to improve further and refine the efficacy of texaphyrins as compounds that may be applied in the struggle against cancer. Chapter 2 details the synthesis of bismuth(III) and lead(II)-texaphyrin complexes that could potentially find use as [alpha]-core emitters for radiotherapy. In principle, porphyrins would ostensibly appear to be ideal ligands for use in radiotherapy due to their tumor-localizing ability. However, Bi(III)- and Pb(II)-porphyrin complexes are extremely rare, most reflecting the vastly challenging synthesis of these compounds as well as their general lack of stability. These limitations provided an incentive for us to use texaphyrins as more versatile ligands to prepare and fully characterize stable bismuth(III) and lead(II) complexes. To be of interest in future medical applications, we needed to prepare these complexes quickly as compared to the relevant time scales set by the half-lives of the isotopes targeted for use in radiotherapy. This goal was successfully realized. As mentioned above, texaphyrin is able to form stable complexes with a large variety of metals particularly in the lanthanide series. Gadolinium(III) complexes of texaphyrin have been studied in considerable detail. Chapter 3 details the synthesis and conjugation methods used to develop a texaphyrin conjugated dual mode nanoparticle contrast agent. This project has been done in collaboration with the group of Prof. Jinwoo Cheon (Yonsei University, Seoul, Korea), who demonstrated fascinating results with the texaphyrin functionalized nanoparticles. Not only do these conjugates act as improved magnetic resonance contrast agents displaying enhanced signals in both the T1 and T2 MRI modes, but also serve to sensitize apoptotic hyperthermia. It is this latter, double effector feature, that has been most extensively studied to date. Chapter 4 of this dissertation describes work done in close collaboration with Dr. Natalie Barkey and Dr. David Morse (Moffitt Cancer Center, Tampa, FL) where a gadolinium texaphyrin complex was developed that is able to target the melanocortin 1 receptor (MC1R) when encapsulated in a micellar system. As detailed in this Chapter, these collaborateurs demonstrated that these gadolinium-texaphyrin micelles are able to target MC1R-expressing xenograft tumors in vivo. This work relied on the supply of a new set of texaphyrin derivatives that were prepared and characterized as part of this dissertation work Chapter 5 of this disseration introduces sapphyrins, another class of expanded porphyrins with tumor selectivity. This project is based on the hypothesis that a direct linkage of sapphyrin with an anticancer agent based on ruthenium(II) could improve the efficacy of both compounds. Since sapphyrins exhibit limited ability to form stable complexes with transition metals, an appended 1,10-phenanthroline unit was chosen as an efficient N-donor aromatic ligand for ruthenium(II). Therefore, extensive synthetic efforts were made to form this sapphyrin-1,10-phenanthroline construct in an effort to stabilize a mixed sapphyrin-metallo-phenanthroline complex. Finally, Chapter 6 of this dissertation demonstrates the author's efforts to synthesize a planar rosarin species. Non-aromatic and non-planar rosarins have been known for over two decades. Through structural modification of the compound, namely through linking of both [Beta] positions on the bipyrrole unit, a new planar rosarin species has been synthesized exhibiting Hückel antiaromaticity. / text

Porphyrins

Expanded porphyrins

Anticancer agents

MRI contrast agents

Radioemitters

Antiaromaticity

The Siamese-Twin Porphyrin and its Metal Complexes: Platforms for Multi-Electron Redox Chemistry

Vogel, Anastasia

21 October 2016

No description available.

540

expanded porphyrins

oxidation

macrocycles

manganese

palladium

aromaticity

Chemie  (PPN62138352X)

Chemistry of Novel Expanded Porphyrins with Main Group Elements / 典型元素を用いた新奇な環拡張ポルフィリンの化学

Higashino, Tomohiro

23 July 2014

京都大学 / 0048 / 新制・論文博士 / 博士(理学) / 乙第12840号 / 論理博第1542号 / 新制||理||1578(附属図書館) / 31423 / 京都大学大学院理学研究科化学専攻 / (主査)教授 大須賀 篤弘, 教授 丸岡 啓二, 教授 時任 宣博 / 学位規則第4条第2項該当 / Doctor of Science / Kyoto University / DGAM

expanded porphyrins

aromaticity

main group elements

porphyrinoid

400