Synthesis of Novel Fluorescent Benzothiazole Cyanine Dyes as Potential Imaging Agents

Paranjpe, Shirish

18 December 2012

Near-infrared (NIR) fluorescence imaging has emerged as an attractive non-invasive approach for direct visualization of diseases which depends on the development of stable, highly specific and sensitive optical probes. The NIR region of the electronic spectrum offers a reduction in the background autofluorescence and an increase in the tissue penetration depth. Cyanine dyes have often been considered promising contrast optic agents owing to their photophysical properties. Herein the synthesis of various penta- and heptamethine benzothiazole cyanine dyes has been described and their in vivo imaging efficacy was determined. Varying functionalities on the benzothiazole aromatic ring and changing substituents on the benzothiazolium nitrogen atom reflected subsequent changes in the imaging pattern and have resulted in the development of promising brain targeting agents.

Cyanine dyes

Benzothiazole

Heptamethine

Pentamethine

Near-infrared

Imaging

Brain

Synthesis of Novel Fluorescent Benzothiazole Cyanine Dyes as Potential Imaging Agents

Paranjpe, Shirish

18 December 2012

Near-infrared (NIR) fluorescence imaging has emerged as an attractive non-invasive approach for direct visualization of diseases which depends on the development of stable, highly specific and sensitive optical probes. The NIR region of the electronic spectrum offers a reduction in the background autofluorescence and an increase in the tissue penetration depth. Cyanine dyes have often been considered promising contrast optic agents owing to their photophysical properties. Herein the synthesis of various penta- and heptamethine benzothiazole cyanine dyes has been described and their in vivo imaging efficacy was determined. Varying functionalities on the benzothiazole aromatic ring and changing substituents on the benzothiazolium nitrogen atom reflected subsequent changes in the imaging pattern and have resulted in the development of promising brain targeting agents.

Cyanine dyes

Benzothiazole

Heptamethine

Pentamethine

Near-infrared

Imaging

Brain

Synthesis of Near-Infrared Heptamethine Cyanine Dyes

Gragg, Jamie Loretta

26 April 2010

Carbocyanine dyes are organic compounds containing chains of conjugated methine groups with electron-donating and electron-withdrawing substituents at the terminal heterocycles of the general formula [R1-(CH)n-R2]+X-. The synthetic methodology and optical properties of carbocyanines will be discussed. This thesis consists of two parts: (A) synthesis and optical properties of novel carbocyanine dyes substituted with various amines and the synthesis of unsymmetrical carbocyanine dyes containing monofunctional groups for bioconjugation. (B) synthesis of heptamethine carbocyanine dyes to be used for image-guided surgery. In part A, the synthesis of carbocyanine dyes functionalized with various amines and studies of their optical properties with respect to absorbance, fluorescence, quantum yield and extinction coefficient will be presented. These property studies will aid in designing efficient dyes for future biomedical applications. Part A will also include a one pot synthesis of unsymmetrical carbocyanine dyes functionalized with mono carboxylic acid chains, useful for biomolecule (i.e. proteins, amino acids, etc.) conjugation. Part B will describe the synthesis of novel carbocyanine dyes to be used for cancer image-guided surgery. Cancers are thus far incurable diseases, i.e. there are no drugs currently available to cure cancer; however, by designing a dye to visualize tumor cells will greatly increase the efficiency of cancer removal and hopefully increase the survival rate of cancer patients. The dyes reported in this thesis are superior to commercially available dyes used to visualize and identify various tumors invisible to the naked eye of surgeons with regards to biodistribution and clearance through kidney filtration.

Imaging

Fluorophore

Vilsmeier-Haack

Heterocycle

Quaternary salt

Polymethine

Synthesis

Near-infrared

Carbocyanine

Heptamethine

Cyanine

Dye

Novel Near-Infrared Cyanine Dyes for Fluorescence Imaging in Biological Systems

Fernando, Nilmi T

14 December 2011

Heptamethine cyanine dyes are attractive compounds for imaging purposes in biomedical applications because of their chemical and photophysical properties exhibited in the near-infrared region. A series of meso amino-substituted heptamethine cyanine dyes with indolenine, benz[e]indolenine and benz[c,d]indolenine heterocyclic moieties were synthesized and their spectral properties including fluorescence quntum yield were investigated in ethanol and ethanol/water mixture. Upon substitution with amines, the absorption maxima of the dyes shifted to the lower wavelength region (~600 nm), showed larger Stokes shifts and stronger fluorescence which can be attributed to an excited state intramolecular charge transfer (ICT). High quantum yields were observed for primary amine derivatives and lower quantum yields were observed for secondary amine derivatives. Fluorescence quantum yields are greater for dyes with 3H-indolenine terminal moieties than for dyes with benz[e]indolenine end groups. Benz[c,d]indolenine based heptamethine cyanine dyes exhibited the lowest quantum yield due to aggregation in solution. In general, the benz[e]indolenine hepatemethine cyanines showed high Stokes shifts compared to indolenine dyes. For the meso-chloro dyes, the absorption maxima for the dyes shifted bathochromically in the order of indolenine, benz[e]indolenine and benz[c,d]indolenine.

Benz[e]indolenine

Near-infrared

Heptamethine cyanine dyes

Fluorescence

Indolenine

Photophysical properties

Chemistry

Bioanalytical Applications of Intramolecular H-Complexes of Near Infrared Bis(Heptamethine Cyanine) Dyes

Kim, Junseok

15 July 2008

This dissertation describes the advantages and feasibility of newly synthesized near-infrared (NIR) bis-heptamethine cyanine (BHmC) dyes for non-covalent labeling schemes. The NIR BHmCs were synthesized for biomolecule assay. The advantages of NIR BHmCs for biomolecule labeling and the instrumental advantages of the near-infrared region are also demonstrated. Chapter 1 introduces the theory and applications of dye chemistry. For bioanalysis, this chapter presents covalent and non-covalent labeling. The covalent labeling depends on the functionality of amino acids and the non-covalent labeling relies on the binding site of a protein. Due to the complicated binding process in non-covalent labeling, this chapter also discusses the binding equilibria in spectroscopic and chromatographic analyses. Chapter 2 and 3 evaluate the novel BHmCs for non-covalent labeling with human serum albumin (HSA) and report the influence of micro-environment on BHmCs. The interesting character of BHmCs in aqueous solutions is that the dyes exhibit non- or low-fluorescence compared to their monomer counterpart, RK780. It is due to their H-type closed clam-shell form in the solutions. The addition of HSA or organic solvents opens up the clam-shell form and enhances fluorescence. The binding equilibria are also examed. Chapter 4 provides a brief introduction that summaries the use of capillary electrophoresis (CE), and offers a detailed instrumentation that discusses the importance and advantage of a detector in NIR region for CE separation. Chapter 5 focuses on the use of NIR cyanine dyes with capillary electrcophoresis with near-infrared laser induce fluorescence (CE-NIR-LIF) detection. The NIR dyes with different functional groups show that RK780 is a suitable NIR dye for HSA labeling. The use of BHmCs with CE-NIR-LIF reduces signal noises that are commonly caused by the interaction between NIR cyanine dyes and negatively charged capillary wall. In addition, bovine carbonic anhydrase II (BCA II) is applied to study the influence of hydrophobicity on non-covalent labeling. Finally, chapter 6 presents the conformational dependency of BHmCs on the mobility in capillary and evaluates the further possibility of BHmCs for small molecule detection. Acridine orange (AO) is used as a sample and it breaks up the aggregate and enhances fluorescence. The inserted AO into BHmC changes the mobility in capillary, owing to the conformational changes by AO.

Clam-shell Form

Capillary Electrophoresis (CE)

Laser Induce Fluorescence (LIF)

Bovine Carbonic Anhydrase II (BCA II)

Acridine Orange (AO)

Human Serum Albumin (HSA)

Binding Equilibria

Covalent Labeling

Non-covalent Labeling

Bis-heptamethine Cyanine (BHmC)

Near-infrared (NIR)

Conception et étude de chromophores polyméthines pour l'optique non-linéaire dans le proche infrarouge / Conception and study of polymethine chromophores for nonlinear optics in the near-infrared

Pascal, Simon

27 June 2014

L’objectif de cette thèse consistait à développer des colorants de la famille des polyméthines absorbant dans le proche infrarouge et présentant des propriétés d’optique non-linéaire (ONL) prononcées. De nouveaux chromophores ont été préparés et leurs propriétés spectroscopiques ont été systématiquement étudiées afin d’établir des relations structures-propriétés. Cette stratégie a permis l’identification des facteurs permettant d’exalter la réponse ONL des polyméthines et de prédire leur comportement face à de subtiles modifications structurales. Trois familles de colorants ont été préparées : des monométhines aza-dipyrrométhènes de bore, des heptaméthines symétriques ainsi que des heptaméthines dissymétriques.Dans un premier temps, des aza-bodipys possédant des groupements donneurs périphériques sont synthétisés. Une étude spectroscopique approfondie permet d’identifier les structures présentant une absorption à deux photons importante en vue d’applications en limitation optique aux longueurs d’onde des télécommunications (1500 nm). Le chapitre suivant a pour but de rationaliser les équilibres de la limite cyanine. L’étude de la substitution centrale de nombreux dérivés heptaméthines a permis de moduler leurs propriétés optiques sur une large gamme spectrale et de mettre en évidence une nouvelle structure électronique limite de type bis-dipôle. Parmi cette famille de colorants, des dérivés keto-heptaméthines ont été utilisées en imagerie biologique (cellules et cerveau) par microscopie non-linéaire. Enfin, l’élaboration de structures heptaméthines dissymétriques originales est détaillée dans le dernier chapitre. Ces chromophores ont révélé des propriétés ONL du second ordre idéales pour des applications en modulation électro-optique. / The aim of this thesis consisted in developing dyes from the polymethine family absorbing in the near-infrared (NIR) region and featuring pronounced nonlinear optical (NLO) properties. Several new chromophores have been prepared and their spectroscopic properties have been systematically investigated in order to establish structure-properties relationships. This strategy has permitted the identification of the factors that enhance the NLO response of polymethines and allowed the prediction of their optical behaviour depending on subtle structural modifications. Three families of dyes have been prepared and investigated: boron aza-dipyrro-monomethines (aza-bodipys), symmetrical heptamethines and unsymmetrical heptamethines.In a first time, aza-bodipys possessing electro-donating peripherical substituants has been synthesized. A detailed spectroscopic study allow the identification of structures that present a high two-photon absorption (TPA), towards optical limiting applications at telecommunication wavelengths (1500 nm). The next chapter rationalizes the equilibrium surrounding the cyanine limit. The study of the central substitution of several heptamethines derivatives permitted the fine tuning of their optical properties upon a large spectral region and evidenced a new bis-dipolar electronic structure. Within this dye family, keto heptamethine derivatives has been tested in bio-imaging experiments (living cells and brain) using non-linear microscopy. Finally, the elaboration of original unsymmetrical heptamethines is detailed in the last chapter. These chromophores revealed ideal second order NLO properties for applications in electro-optic modulation.

Optique non-linéaire

Absorption à deux photons

Colorants infrarouges

Polyméthines

Aza dipyrrométhènes de bore

Heptaméthines cyanines

Limitation optique

Imagerie biologique

Modulation électro-optique

Nonlinear optics

Two-photon absorption

Near-infrared dyes

Polymethines

Boron aza dipyrromethenes

Heptamethine cyanines

Optical limiting

Biological imaging

Electro optic modulation