Interplay of multivalency and optical properties of quantum dots: Implications for sensing and actuation in living cells

Quantum dots (QDs) are unique probes due to their special properties (brightness, photostability, narrowband emission and broadband absorption), and excellent bio(chemical)compatibility for imaging structures and functions of living cells. When functionalized with ligands, they enable the recognitio...

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Detalles Bibliográficos
Autores principales: Menéndez, G., Roberti, M.J., Sigot, V., Etchehon, M., Jovin, T.M., Erijman, J.E.A.
Formato: CONF
Materias:
α-synuclein
Amyloid protein aggregation
Confocal microscopy.
Imaging
Nanoeffectors
Parkinson's disease
pH nanosensors
Amyloid proteins
Broadband absorption
Dynamic process
Functionalized
Imaging structure
In-vitro
Live cell
Living cell
Multivalency
Nano-devices
Nanoactuators
Narrow-band emission
Photo-stability
Quantum Dot
Quantum dots
Sensing characteristics
Single molecule level
Small molecules
Special properties
Synuclein
Cell membranes
Confocal microscopy
Energy transfer
Glycoproteins
Molecules
Nanoparticles
Nanosensors
Optical properties
Probes
Semiconductor quantum dots
Agglomeration
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_16057422_v7189_n_p_Menendez
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_16057422_v7189_n_p_Menendez
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spelling todo:paper_16057422_v7189_n_p_Menendez2023-10-03T16:27:50Z Interplay of multivalency and optical properties of quantum dots: Implications for sensing and actuation in living cells Menéndez, G. Roberti, M.J. Sigot, V. Etchehon, M. Jovin, T.M. Erijman, J.E.A. α-synuclein Amyloid protein aggregation Confocal microscopy. Imaging Nanoeffectors Parkinson's disease pH nanosensors Amyloid protein aggregation Amyloid proteins Broadband absorption Dynamic process Functionalized Imaging Imaging structure In-vitro Live cell Living cell Multivalency Nano-devices Nanoactuators Nanoeffectors Narrow-band emission Parkinson's disease Photo-stability Quantum Dot Quantum dots Sensing characteristics Single molecule level Small molecules Special properties Synuclein Cell membranes Confocal microscopy Energy transfer Glycoproteins Molecules Nanoparticles Nanosensors Optical properties Probes Semiconductor quantum dots Agglomeration Quantum dots (QDs) are unique probes due to their special properties (brightness, photostability, narrowband emission and broadband absorption), and excellent bio(chemical)compatibility for imaging structures and functions of living cells. When functionalized with ligands, they enable the recognition of specific targets and the tracking of dynamic processes for extended periods of time, detecting biomolecules with a sensitivity extending to the single molecule level. Thus, devices and probes based on such nanoparticles are very powerful tools for studying essential processes underlying the functions and regulation of living cells. Here we present nanosensors and nanoactuators based on QDs in which the multivalency of these particles plays an essential role in the functionality and sensing characteristics of the nanodevices. Two examples are discussed, the first being pH nanosensors based on the interplay of the multivalency and energy transfer between the nanoparticles and small molecules on their surface, and the second nanoactuators in which a controlled number of molecules of the amyloid protein α-synuclein (AS) specifically regulate the aggregation of fluorescently labeled bulk AS protein both in vitro and in live cells.©; 2009 SPIE. Fil:Menéndez, G. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Roberti, M.J. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. CONF info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_16057422_v7189_n_p_Menendez
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic α-synuclein
Amyloid protein aggregation
Confocal microscopy.
Imaging
Nanoeffectors
Parkinson's disease
pH nanosensors
Amyloid protein aggregation
Amyloid proteins
Broadband absorption
Dynamic process
Functionalized
Imaging
Imaging structure
In-vitro
Live cell
Living cell
Multivalency
Nano-devices
Nanoactuators
Nanoeffectors
Narrow-band emission
Parkinson's disease
Photo-stability
Quantum Dot
Quantum dots
Sensing characteristics
Single molecule level
Small molecules
Special properties
Synuclein
Cell membranes
Confocal microscopy
Energy transfer
Glycoproteins
Molecules
Nanoparticles
Nanosensors
Optical properties
Probes
Semiconductor quantum dots
Agglomeration
spellingShingle α-synuclein
Amyloid protein aggregation
Confocal microscopy.
Imaging
Nanoeffectors
Parkinson's disease
pH nanosensors
Amyloid protein aggregation
Amyloid proteins
Broadband absorption
Dynamic process
Functionalized
Imaging
Imaging structure
In-vitro
Live cell
Living cell
Multivalency
Nano-devices
Nanoactuators
Nanoeffectors
Narrow-band emission
Parkinson's disease
Photo-stability
Quantum Dot
Quantum dots
Sensing characteristics
Single molecule level
Small molecules
Special properties
Synuclein
Cell membranes
Confocal microscopy
Energy transfer
Glycoproteins
Molecules
Nanoparticles
Nanosensors
Optical properties
Probes
Semiconductor quantum dots
Agglomeration
Menéndez, G.
Roberti, M.J.
Sigot, V.
Etchehon, M.
Jovin, T.M.
Erijman, J.E.A.
Interplay of multivalency and optical properties of quantum dots: Implications for sensing and actuation in living cells
topic_facet α-synuclein
Amyloid protein aggregation
Confocal microscopy.
Imaging
Nanoeffectors
Parkinson's disease
pH nanosensors
Amyloid protein aggregation
Amyloid proteins
Broadband absorption
Dynamic process
Functionalized
Imaging
Imaging structure
In-vitro
Live cell
Living cell
Multivalency
Nano-devices
Nanoactuators
Nanoeffectors
Narrow-band emission
Parkinson's disease
Photo-stability
Quantum Dot
Quantum dots
Sensing characteristics
Single molecule level
Small molecules
Special properties
Synuclein
Cell membranes
Confocal microscopy
Energy transfer
Glycoproteins
Molecules
Nanoparticles
Nanosensors
Optical properties
Probes
Semiconductor quantum dots
Agglomeration
description Quantum dots (QDs) are unique probes due to their special properties (brightness, photostability, narrowband emission and broadband absorption), and excellent bio(chemical)compatibility for imaging structures and functions of living cells. When functionalized with ligands, they enable the recognition of specific targets and the tracking of dynamic processes for extended periods of time, detecting biomolecules with a sensitivity extending to the single molecule level. Thus, devices and probes based on such nanoparticles are very powerful tools for studying essential processes underlying the functions and regulation of living cells. Here we present nanosensors and nanoactuators based on QDs in which the multivalency of these particles plays an essential role in the functionality and sensing characteristics of the nanodevices. Two examples are discussed, the first being pH nanosensors based on the interplay of the multivalency and energy transfer between the nanoparticles and small molecules on their surface, and the second nanoactuators in which a controlled number of molecules of the amyloid protein α-synuclein (AS) specifically regulate the aggregation of fluorescently labeled bulk AS protein both in vitro and in live cells.©; 2009 SPIE.
format CONF
author Menéndez, G.
Roberti, M.J.
Sigot, V.
Etchehon, M.
Jovin, T.M.
Erijman, J.E.A.
author_facet Menéndez, G.
Roberti, M.J.
Sigot, V.
Etchehon, M.
Jovin, T.M.
Erijman, J.E.A.
author_sort Menéndez, G.
title Interplay of multivalency and optical properties of quantum dots: Implications for sensing and actuation in living cells
title_short Interplay of multivalency and optical properties of quantum dots: Implications for sensing and actuation in living cells
title_full Interplay of multivalency and optical properties of quantum dots: Implications for sensing and actuation in living cells
title_fullStr Interplay of multivalency and optical properties of quantum dots: Implications for sensing and actuation in living cells
title_full_unstemmed Interplay of multivalency and optical properties of quantum dots: Implications for sensing and actuation in living cells
title_sort interplay of multivalency and optical properties of quantum dots: implications for sensing and actuation in living cells
url http://hdl.handle.net/20.500.12110/paper_16057422_v7189_n_p_Menendez
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AT sigotv interplayofmultivalencyandopticalpropertiesofquantumdotsimplicationsforsensingandactuationinlivingcells
AT etchehonm interplayofmultivalencyandopticalpropertiesofquantumdotsimplicationsforsensingandactuationinlivingcells
AT jovintm interplayofmultivalencyandopticalpropertiesofquantumdotsimplicationsforsensingandactuationinlivingcells
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