Acidic Condensation of BODIPYs with Aldehydes: A Quick and Versatile Route to Alkenyl‐BODIPYs and C(sp<sup>3</sup>)‐Connected DYEmers

Ahrens, Johannes; Cordes, Birte; Wicht, Richard; Wolfram, Benedikt; Bröring, Martin

doi:10.1002/chem.201601568

Cited by 35 publications

(5 citation statements)

References 62 publications

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“…BODIPY motifs, which are predominantly known for serving as powerful fluorescent tags and sensing platforms in life sciences, − also entered the field of supramolecular chemistry and profit from a toolbox of versatile postfunctionalizations. − While a range of different conjugation modes was introduced, most of them suffer from either a conformational space that is too restricted (methylene tether) , or detrimental π-overlap (direct sp 2 –sp 2 , , alkynyl , ) to enable defined alignments. However, such alignments would be necessary to achieve narrowed absorption/emission profiles as consequence of J-aggregation with delocalized excitons.…”

Section: Introductionmentioning

confidence: 99%

Ultrafast Resonance Energy Transfer in Ethylene-Bridged BODIPY Heterooligomers: From Frenkel to Förster Coupling Limit

et al. 2021

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A series of distinct BODIPY heterooligomers (dyads, triads, and tetrads) comprising a variable number of typical green BODIPY monomers and a terminal red-emitting styryl-equipped species acting as an energy sink was prepared and subjected to computational and photophysical investigations in solvent media. An ethylene tether between the single monomeric units provides a unique foldameric system, setting the stage for a systematic study of excitation energy transfer processes (EET) on the basis of nonconjugated oscillators. The influence of stabilizing β-ethyl substituents on conformational space and the disorder of site energies and electronic couplings was addressed. In this way both the strong (Frenkel) and the weak (Förster) coupling limit could be accessed within a single system: the Frenkel limit within the strongly coupled homooligomeric green donor subunit and the Förster limit at the terminal heterosubstituted ethylene bridge. Femtosecond transient-absorption spectroscopy combined with mixed quantum-classical dynamic simulations demonstrate the limitations of the Förster resonance energy transfer (FRET) theory and provide a consistent framework to elucidate the trend of increasing relaxation lifetimes at higher homologues, revealing one of the fastest excitation energy transfer processes detected to date with a corresponding lifetime of 39 fs.

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Section: Introductionmentioning

confidence: 99%

Ultrafast Resonance Energy Transfer in Ethylene-Bridged BODIPY Heterooligomers: From Frenkel to Förster Coupling Limit

et al. 2021

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“…The formation of BODIPY DYEmers also gains from the use of non‐symmetric BODIPY precursors as losses due to the formation of higher oligomers or macrocycles can be avoided . Two such DYEmers, the directly linked α,α‐DYEmer 18 and the methylene‐bridged compound 19 , were prepared from 1 by using the newly established methods of oxidative coupling and acidic condensation with formaldehyde, respectively (Scheme ). Both compounds form as stable and intensely fluorescing dyes in acceptable yields of 48 and 70 %, respectively.…”

Section: Resultsmentioning

confidence: 99%

One‐Pot Preparation of Non‐Symmetric meso‐Aryl‐BODIPYs: Functional Derivatives with Unusual Reactivity

et al. 2016

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The formation of meso‐aryl‐BODIPYs (boron dipyrrins) through the acidic condensation of 3,4‐dialkylpyrroles with aromatic aldehydes, followed by 2,3‐dichloro‐5,6‐dicyano‐1,4‐benzoquinone (DDQ) oxidation and BF2 complexation, has been reviewed. Surprisingly, it was found that the major products from these reactions were not the anticipated symmetric BODIPYs, but non‐symmetric derivatives carrying one benzyl substituent at the BODIPY α position. The best yields and simple purification conditions were be achieved if the oxidant was not employed in the one‐pot reaction sequence. Electron‐rich benzaldehydes provided the best results, whereas precursors with electron‐withdrawing substituents gave significant amounts of the symmetric BODIPYs as side‐products. This unexpected result can be rationalized mechanistically on the basis of two reaction pathways that diverge from a common intermediate at an early step in the condensation sequence. Preliminary reactivity investigations showed chlorination to give unexpected results, but a typical substitution and coupling chemistry.

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“…( 1) BODIPY oligomerization of non-conjugated hybrid fluorophores. Broring et al developed a series of BODIPY dimers and tetramers 228-236 in 2016 [141] (Figure 16 and Table 13).…”

Section: Oligomerization Of Non-conjugated Hybrid Fluorophoresmentioning

confidence: 99%

“…Broring et al . developed a series of BODIPY dimers and tetramers 228 – 236 in 2016 [141] (Figure 16 and Table 13). Compared to the BODIPY monomers, these dimers have excellent molar extinction coefficients and fluorescence quantum yields, except for 232 and 233 , but their absorption and emission wavelengths are not significantly lengthened.…”

Section: Photophysical Properties Of Hybrid Fluorophoresmentioning

confidence: 99%

Rational Design and Biological Application of Hybrid Fluorophores

Zhang,

Qu,

Zhang

et al. 2024

Chemistry A European J

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Fluorophores are considered powerful tools for not only enabling the visualization of cell structures, substructures, and biological processes, but also making for the quantitative and qualitative measurement of various analytes in living systems. However, most fluorophores do not meet the diverse requirements for biological applications in terms of their photophysical and biological properties. Hybridization is an important strategy in molecular engineering that provides fluorophores with complementarity and multifunctionality. This review summarizes the basic strategies of hybridization with four classes of fluorophores, including xanthene, cyanine, coumarin, and BODIPY with a focus on their structure‐property relationship (SPR) and biological applications. This review aims to provide rational hybrid ideas for expanding the reservoir of knowledge regarding fluorophores and promoting the development of newly produced fluorophores for applications in the field of life sciences.

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Acidic Condensation of BODIPYs with Aldehydes: A Quick and Versatile Route to Alkenyl‐BODIPYs and C(sp³)‐Connected DYEmers

Cited by 35 publications

References 62 publications

Ultrafast Resonance Energy Transfer in Ethylene-Bridged BODIPY Heterooligomers: From Frenkel to Förster Coupling Limit

Ultrafast Resonance Energy Transfer in Ethylene-Bridged BODIPY Heterooligomers: From Frenkel to Förster Coupling Limit

One‐Pot Preparation of Non‐Symmetric meso‐Aryl‐BODIPYs: Functional Derivatives with Unusual Reactivity

Rational Design and Biological Application of Hybrid Fluorophores

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Acidic Condensation of BODIPYs with Aldehydes: A Quick and Versatile Route to Alkenyl‐BODIPYs and C(sp3)‐Connected DYEmers

Cited by 35 publications

References 62 publications

Ultrafast Resonance Energy Transfer in Ethylene-Bridged BODIPY Heterooligomers: From Frenkel to Förster Coupling Limit

Ultrafast Resonance Energy Transfer in Ethylene-Bridged BODIPY Heterooligomers: From Frenkel to Förster Coupling Limit

One‐Pot Preparation of Non‐Symmetric meso‐Aryl‐BODIPYs: Functional Derivatives with Unusual Reactivity

Rational Design and Biological Application of Hybrid Fluorophores

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Product

Resources

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Acidic Condensation of BODIPYs with Aldehydes: A Quick and Versatile Route to Alkenyl‐BODIPYs and C(sp³)‐Connected DYEmers