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Design Principles for Two-Dimensional Molecular Aggregates Using Kasha's Model: Tunable Photophysics in Near and Short-Wave Infrared
Technologies
which utilize near-infrared (700 – 1000 nm) and short-wave infrared (1000 –
2000 nm) electromagnetic radiation have applications in deep-tissue imaging,
telecommunications and satellite telemetry due to low scattering and decreased
background signal in this spectral region. It is therefore necessary to develop
materials that absorb light efficiently beyond 1000 nm. Transition dipole
moment coupling (e.g. J-aggregation) allows for redshifted excitonic states and
provides a pathway to highly absorptive electronic states in the infrared. We present aggregates of two cyanine dyes whose
absorption peaks redshift dramatically upon aggregation in water from ~800
nm to 1000 nm and 1050 nm respectively with sheet-like morphologies and high
molar absorptivities (e ~ 105 M-1cm-1). We use Frenkel exciton theory to extend
Kasha’s model for J and H aggregation and describe the excitonic states of
2-dimensional aggregates whose slip is controlled by steric hindrance in the
assembled structure. A consequence of the increased dimensionality is the
phenomenon of an intermediate “I-aggregate”, one which redshifts yet displays
spectral signatures of band-edge dark states akin to an H-aggregate. We
distinguish between H-, I- and J-aggregates by showing the relative position of
the bright (absorptive) state within the density of states using temperature
dependent spectroscopy. I-aggregates hold potential for applications as charge
injection moieties for semiconductors and donors for energy transfer in NIR and
SWIR. Our results can be used to better design chromophores with predictable
and tunable aggregation with new photophysical properties
The Effect of Varying Short-Chain Alkyl Substitution on the Molar Absorptivity and Quantum Yield of Cyanine Dyes
The effect of varying short-chain alkyl substitution of the indole nitrogens on the spectroscopic properties of cyanine dyes was examined. Molar absorptivities and fluorescence quantum yields were determined for a set of pentamethine dyes and a set of heptamethine dyes for which the substitution of the indole nitrogen was varied. For both sets of dyes, increasing alkyl chain length resulted in no significant change in quantum yield or molar absorptivity. These results may be useful in designing new cyanine dyes for analytical applications and predicting their spectroscopic properties
Approaches to overcome flow cytometry limitations in the analysis of cells from veterinary relevant species
BACKGROUND: Flow cytometry is a powerful tool for the multiparameter analysis of leukocyte subsets on the single cell level. Recent advances have greatly increased the number of fluorochrome-labeled antibodies in flow cytometry. In particular, an increase in available fluorochromes with distinct excitation and emission spectra combined with novel multicolor flow cytometers with several lasers have enhanced the generation of multidimensional expression data for leukocytes and other cell types. However, these advances have mainly benefited the analysis of human or mouse cell samples given the lack of reagents for most animal species. The flow cytometric analysis of important veterinary, agricultural, wildlife, and other animal species is still hampered by several technical limitations, even though animal species other than the mouse can serve as more accurate models of specific human physiology and diseases.
RESULTS: Here we present time-tested approaches that our laboratory regularly uses in the multiparameter flow cytometric analysis of ovine leukocytes. The discussed approaches will be applicable to the analysis of cells from most animal species and include direct modification of antibodies by covalent conjugation or Fc-directed labeling (Zenon™ technology), labeled secondary antibodies and other second step reagents, labeled receptor ligands, and antibodies with species cross-reactivity.
CONCLUSIONS: Using refined technical approaches, the number of parameters analyzed by flow cytometry per cell sample can be greatly increased, enabling multidimensional analysis of rare samples and giving critical insight into veterinary and other less commonly analyzed species. By maximizing information from each cell sample, multicolor flow cytometry can reduce the required number of animals used in a study
Ultrafast fluorescent decay induced by metal-mediated dipole-dipole interaction in two-dimensional molecular aggregates
Two-dimensional molecular aggregate (2DMA), a thin sheet of strongly
interacting dipole molecules self-assembled at close distance on an ordered
lattice, is a fascinating fluorescent material. It is distinctively different
from the single or colloidal dye molecules or quantum dots in most previous
research. In this paper, we verify for the first time that when a 2DMA is
placed at a nanometric distance from a metallic substrate, the strong and
coherent interaction between the dipoles inside the 2DMA dominates its
fluorescent decay at picosecond timescale. Our streak-camera lifetime
measurement and interacting lattice-dipole calculation reveal that the
metal-mediated dipole-dipole interaction shortens the fluorescent lifetime to
about one half and increases the energy dissipation rate by ten times than
expected from the noninteracting single-dipole picture. Our finding can enrich
our understanding of nanoscale energy transfer in molecular excitonic systems
and may designate a new direction for developing fast and efficient
optoelectronic devices.Comment: 9 pages, 6 figure
Design and Application of Task-Specific GUMBOS and NanoGUMBOS for Sensing and Separation
The work presented in this dissertation employs task-specific materials for sensing and protein separation applications. These materials were derived from a group of uniform materials based on organic salts (GUMBOS). GUMBOS are organic salts similar to ionic liquids, but have melting points ranging from 25 to 250 °C. As with ionic liquids, the properties of GUMBOS can be easily tuned by changing the counter-ion. Thus, task-specific GUMBOS can be designed and prepared with properties that are beneficial for applications in sensing or protein separation. In this dissertation, the selective responsive behavior of a series of GUMBOS and nanomaterials derived from GUMBOS (nanoGUMBOS) were evaluated. Firstly, binary nanoGUMBOS, containing two cyanine cations, were synthesized and characterized. Based on significant spectral overlap and differences in reactivity towards hydroxyl radicals, the two cyanine cations in the binary nanoGUMBOS were able to generate a ratiometric fluorescence response. These results suggest a promising ratiometric probe for detection and quantification of hydroxyl radicals. This approach of investigating binary nanoprobes will serve as the basis for designing other cyanine-based fluorescent probes for biosensing and imaging. Secondly, a series of cyanine-based GUMBOS were combined to serve as a sensor array for detection of proteins. The cyanine-based sensor elements utilized in this sensor array, exhibit different aggregation behaviors when mixed with the seven proteins, giving various fluorescence responses. The resulting responses exhibited cross-reactive patterns, which can be analyzed to discriminate proteins at a low concentration. Finally, nanoGUMBOS derived from imidazolium ionic liquids and magnetic dysprosium-based anions were designed as magnetic, nanoadsorbent materials for selective hemoglobin isolation. These nanoGUMBOS were successfully applied in selective hemoglobin (Hb) isolation from human whole blood. All studies presented in this dissertation demonstrate promising advantages of GUMBOS-based materials in the field of sensing and protein separation
Validation and implementation of a diagnostic algorithm for DNA Detection of Bordetella pertussis, B. parapertussis, and B-holmesii in a Pediatric Referral Hospital in Barcelona, Spain
This study aimed to validate a comprehensive diagnostic protocolbased on real-time PCR for the rapid detection and identification ofBordetella per-tussis,Bordetella parapertussis, andBordetella holmesii, as well as its implementationin the diagnostic routine of a reference children’s hospital. The new algorithm in-cluded a triplex quantitative PCR (qPCR) targeting IS481gene (inB. pertussis,B. hol-mesii, and someBordetella bronchisepticastrains), pIS1001(B. parapertussis-specific)andrnaseP as the human internal control. Two confirmatory singleplex tests forB.pertussis(ptxA-Pr) andB. holmesii(hIS1001) were performed if IS481was positive. An-alytical validation included determination of linear range, linearity, efficiency, preci-sion, sensitivity, and a reference panel with clinical samples. Once validated, the newalgorithm was prospectively implemented in children with clinical suspicion ofwhooping cough presenting to Hospital Sant Joan de Deu (Barcelona, Spain) over12 months. Lower limits of detection obtained were 4.4, 13.9, and 27.3 genomicequivalents/ml of sample for IS481(onB. pertussis), pIS1001and hIS1001, and 777.9forptxA-Pr. qPCR efficiencies ranged from 86.0% to 96.9%. Intra- and interassay vari-abilities were 3% and 5%, respectively. Among 566 samples analyzed,B. pertus-sis,B. holmesii, andB. parapertussiswere detected in 11.1%, 0.9% (only in females 4 years old), and 0.2% of samples, respectively. The new algorithm proved to be auseful microbiological diagnostic tool for whooping cough, demonstrating a low rateof other non-pertussis Bordetellaspecies in our surveilled areaPeer ReviewedPostprint (author's final draft
Spectroscopic Studies of Carbocyanine and 2,4,6- Trisubstituted Pyridine Dyes for Bioanalytical and pH Indicating Applications
In part A, the effect of varying short-chain alkyl substitution on the spectroscopic properties of cyanine dyes was examined. Molar absorptivities and quantum yields were determined for groups of pentamethine and heptamethine dyes for which the substitution of the indole nitrogen was varied. For both sets of dyes, increasing alkyl chain length did not significantly change quantum yield or molar absorptivity. These results may be useful in designing new cyanine dyes.
In part B, the effect of structure on the suitability of 2,4,6-trisubstituted pyridines as color pH indicators was studied by determining spectral effects of protonation, molar absorptivities, pKa values, and the structural origin of the spectral behavior. Good color indicating properties result from aniline substitution at the 4 position of pyridine and electron donating substitution at the 2 and 6 positions of pyridine, which provide a strong red shift in the spectra and greater red shifted peak absorptivity, respectively
The Effect of Varying Short-Chain Alkyl Substitution on the Molar Absorptivity and Quantum Yield of Cyanine Dyes
The effect of varying short-chain alkyl substitution of the indole nitrogens on the spectroscopic properties of cyanine dyes was examined. Molar absorptivities and fluorescence quantum yields were determined for a set of pentamethine dyes and a set of heptamethine dyes for which the substitution of the indole nitrogen was varied. For both sets of dyes, increasing alkyl chain length resulted in no significant change in quantum yield or molar absorptivity
A new twist on PIFE: photoisomerisation-related fluorescence enhancement
PIFE was first used as an acronym for protein-induced fluorescence
enhancement, which refers to the increase in fluorescence observed upon the
interaction of a fluorophore, such as a cyanine, with a protein. This
fluorescence enhancement is due to changes in the rate of cis/trans
photoisomerisation. It is clear now that this mechanism is generally applicable
to interactions with any biomolecule and, in this review, we propose that PIFE
is thereby renamed according to its fundamental working principle as
photoisomerisation-related fluorescence enhancement, keeping the PIFE acronym
intact. We discuss the photochemistry of cyanine fluorophores, the mechanism of
PIFE, its advantages and limitations, and recent approaches to turn PIFE into a
quantitative assay. We provide an overview of its current applications to
different biomolecules and discuss potential future uses, including the study
of protein-protein interactions, protein-ligand interactions and conformational
changes in biomolecules.Comment: No Comment
Cyanine-Flavonol Hybrids for Near-Infrared Light-Activated Delivery of Carbon Monoxide
Carbon monoxide (CO) is an endogenous signaling molecule that controls a number of physiological processes. To circumvent the inherent toxicity of CO, light-activated CO-releasing molecules (photoCORMs) have emerged as an alternative for its administration. However, their wider application requires photoactivation using biologically benign visible and near-infrared (NIR) light. In this work, a strategy to access such photoCORMs by fusing two CO-releasing flavonol moieties with a NIR-absorbing cyanine dye is presented. These hybrids liberate two molecules of CO in high chemical yields upon activation with NIR light up to 820 nm and exhibit excellent uncaging cross-sections, which surpass the state-of-the-art by two orders of magnitude. Furthermore, the biocompatibility and applicability of the system in vitro and in vivo are demonstrated, and a mechanism of CO release is proposed. It is hoped that this strategy will stimulate the discovery of new classes of photoCORMs and accelerate the translation of CO-based phototherapy into practice
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