A Molecular Rotor that Measures Dynamic Changes of Lipid Bilayer Viscosity Caused by Oxidative Stress

Vyšniauskas, Aurimas; Qurashi, Maryam; Kuimova, Marina K.

doi:10.1002/chem.201601925

Cited by 38 publications

(50 citation statements)

References 56 publications

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“…We have previously demonstrated using two independent molecular rotors that PDT of cells causes a large viscosity increase in vitro 30 31 . Furthermore, we have investigated the mechanism of this process using a third independent molecular rotor, BODIPY1, incorporated into model lipid bilayers 34 . In all cases we found that photooxidation of lipids or cellular components caused by PDT results in a large increase in viscosity.…”

Section: Discussionmentioning

confidence: 99%

“…Importantly, fluorescence ratiometric and lifetime detection from molecular rotors allowed to overcome difficulties associated with an unknown fluorophore concentration and thus enabled quantitative viscosity mapping to be performed. These measurements provided the wealth of biologically relevant information on model lipid membranes 17 18 19 , bacterial 20 21 22 and eukaryotic cells and cellular organelles 23 24 25 26 27 28 29 30 31 32 33 , and allowed viscosity monitoring during lipid (photo)oxidation 34 , cell death 31 , bacterial sporulation and deactivation 20 21 , and bacterial membrane viscosity changes in response to variations in temperature 22 . While the fluorescence-based approaches, including molecular rotors, allowed the measurements of viscosity and diffusion on a single cell level in vitro , the in vivo viscosity monitoring has not yet been realized.…”

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confidence: 99%

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Imaging tumor microscopic viscosity in vivo using molecular rotors

Shimolina

Izquierdo

López‐Duarte

et al. 2017

Sci Rep

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The microscopic viscosity plays an essential role in cellular biophysics by controlling the rates of diffusion and bimolecular reactions within the cell interior. While several approaches have emerged that have allowed the measurement of viscosity and diffusion on a single cell level in vitro, the in vivo viscosity monitoring has not yet been realized. Here we report the use of fluorescent molecular rotors in combination with Fluorescence Lifetime Imaging Microscopy (FLIM) to image microscopic viscosity in vivo, both on a single cell level and in connecting tissues of subcutaneous tumors in mice. We find that viscosities recorded from single tumor cells in vivo correlate well with the in vitro values from the same cancer cell line. Importantly, our new method allows both imaging and dynamic monitoring of viscosity changes in real time in live animals and thus it is particularly suitable for diagnostics and monitoring of the progress of treatments that might be accompanied by changes in microscopic viscosity.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

Imaging tumor microscopic viscosity in vivo using molecular rotors

Shimolina

Izquierdo

López‐Duarte

et al. 2017

Sci Rep

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“…Fortunately, relatively fast and convenient measurements of viscosity can be achieved with an emerging class of fluorescent compounds—molecular rotors . Previously, they have been used for viscosity sensing in polymers, polymersomes, aerosols, model lipid bilayers, protein aggregates, and live cells . Within cells, viscosity measurements have been performed in mitochondria, lysosomes, an endoplasmic reticulum, and a plasma membrane .…”

Section: Introductionmentioning

confidence: 99%

“…BODIPY‐C 12 (Figure ) and its variations containing other ether groups as substituents are arguably the most widely used molecular rotors . These rotors have similar photophysical properties, and their main advantage is monoexponential fluorescence decay, which simplifies data analysis and interpretation .…”

Section: Introductionmentioning

confidence: 99%

Enhancing the Viscosity‐Sensitive Range of a BODIPY Molecular Rotor by Two Orders of Magnitude

Toliautas

Dodonova

Žvirblis

et al. 2019

Chemistry A European J

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Molecular rotors are ac lass of fluorophores that enable convenient imaging of viscosity inside microscopic sampless uch as lipid vesicleso rlive cells. Currently, rotor compounds containingaboron-dipyrromethene( BODIPY) group are among the most promisingv iscosity probes. In this work, it is reportedt hat by addingh eavy-electron-withdrawing ÀNO 2 groups, the viscosity-sensitiver ange of a BODIPYp robe is drasticallye xpandedf rom 5-1500cPt o 0.5-50 000 cP.T he improved range makes it, to our knowledge, the first hydrophobic molecular rotor applicable not only at moderate viscosities but also for viscosity measurements in highlyv iscous samples. Furthermore, the photo-physicalm echanism of the BODIPY molecular rotors under study has been determined by performing quantum chemical calculations and transienta bsorption experiments. This mechanism demonstrates how BODIPY molecular rotors work in general,w hy the ÀNO 2 group causes such an improvement, and why BODIPYm olecular rotors suffer from undesirable sensitivity to temperature. Overall,b esides reporting av iscosity probe with remarkable properties, the results obtainede xpandt he general understanding of molecular rotors and show away to use the knowledge of their molecular actionm echanism for augmenting their viscositysensing properties.[**] BODIPY = boron-dipyrromethene.Supporting Information and the ORCID identification number(s) for the author(s) of this articlecan be found under: https://doi.

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“…Synthetic molecular rotors have high potential in various photonic, electronic, and biological applications . In molecular rotors, rotational groups (“rotators”), linked by either covalent bonds or noncovalent coordination bonds to a part of the molecular rotors, are rotated along an axle. In π‐conjugated molecular rotors, the rotation of rotators is affected by the π‐electron delocalization characteristics, resulting in a change of photophysical properties related to electronic states, such as fluorescence and charge transfer .…”

Section: Introductionmentioning

confidence: 99%

Molecular Viscosity Sensors with Two Rotators for Optimizing the Fluorescence Intensity–Contrast Trade‐Off

Lee

Heo

et al. 2017

Chemistry A European J

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A series of fluorescent molecular rotors obtained by introducing two rotational groups ("rotators"), which exhibit different rotational and electron-donating abilities, are discussed. Whereas the control molecular rotor, PH, includes a single rotator (the widely used phenyl group), the PO molecular rotors consist of two rotators (a phenyl group and an alkoxy group), which exhibit simultaneous strongly electron-donating and easy rotational abilities. Compared with the control rotor PH, PO molecular rotors exhibited one order of magnitude higher quantum yield (fluorescence intensity) and simultaneously exhibited significantly higher fluorescence contrast. These properties are directly related to the strong electron-donating ability and low energy barrier of rotation of the alkoxy group, as confirmed by dynamic fluorescence experiments and quantum chemical calculations. The PO molecular rotors exhibited two fluorescence relaxation pathways, whereas the PH molecular rotor exhibited a single fluorescence relaxation pathway. Cellular fluorescence imaging with PO molecular rotors for mapping cellular viscosity was successfully demonstrated.

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A Molecular Rotor that Measures Dynamic Changes of Lipid Bilayer Viscosity Caused by Oxidative Stress

Cited by 38 publications

References 56 publications

Imaging tumor microscopic viscosity in vivo using molecular rotors

Imaging tumor microscopic viscosity in vivo using molecular rotors

Enhancing the Viscosity‐Sensitive Range of a BODIPY Molecular Rotor by Two Orders of Magnitude

Molecular Viscosity Sensors with Two Rotators for Optimizing the Fluorescence Intensity–Contrast Trade‐Off

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