Active cellular sensing with quantum dots: Transitioning from research tool to reality; a review

[Display omitted] ► Quantum dots (QDs) have evolved beyond mere cellular labeling reagents. ► Significant advances have been made in QD materials, surface coatings and bioconjugation. ► Cellular targeting/delivery has been achieved using polymers, peptides, proteins. ► Numerous QD-based sensing appl...

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Veröffentlicht in:	Analytica chimica acta 2012-10, Vol.750, p.63-81
Hauptverfasser:	Delehanty, James B., Susumu, Kimihiro, Manthe, Rachel L., Algar, W. Russ, Medintz, Igor L.
Format:	Artikel
Sprache:	eng
Schlagworte:	Analytical chemistry Animals Applied sciences Biological and medical sciences Biomolecules Biosensing Techniques Biosensor Biosensors Biotechnology Cell physiology Cell Tracking Cellular Chemistry Detection Endocytosis Exact sciences and technology Fluorescence Format Fundamental and applied biological sciences. Psychology Global environmental pollution Humans Imaging Ligands Membranes Methods. Procedures. Technologies Molecular and cellular biology Monitoring Peptides - chemistry Peptides - metabolism Pollution Polymers - chemistry Proteins - chemistry Proteins - metabolism Quantum dot Quantum Dots Semiconductors Silicon Dioxide - chemistry Spectrometric and optical methods Theranostics Various methods and equipments
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creator	Delehanty, James B. Susumu, Kimihiro Manthe, Rachel L. Algar, W. Russ Medintz, Igor L.
description	[Display omitted] ► Quantum dots (QDs) have evolved beyond mere cellular labeling reagents. ► Significant advances have been made in QD materials, surface coatings and bioconjugation. ► Cellular targeting/delivery has been achieved using polymers, peptides, proteins. ► Numerous QD-based sensing applications: extracellular, membrane, intracellular. The application of luminescent semiconductor quantum dots (QDs) within a wide range of biological imaging and sensing formats is now approaching its 15th year. The unique photophysical properties of these nanomaterials have long been envisioned as having the potential to revolutionize biosensing within cellular studies that rely on fluorescence. However, it is only now that these materials are making the transition towards accomplishing this goal. With the idea of understanding how to actively incorporate QDs into different types of cellular biosensing, we review the progress in many of the areas relevant to achieving this goal. This includes the synthesis of the QDs themselves, with an emphasis on minimizing potential toxicity, along with the general methods for making these nanocrystalline structures stable in aqueous media. We next survey some methods for conjugating QDs to biomolecules to allow them to participate in active biosensing. Lastly, we extensively review many of the applications where QDs have been demonstrated in an active role in cellular biosensing. These formats cover a wide range of possibilities including where the QDs have contributed to: monitoring the cell's interaction with its extracellular environment; elucidating the complex molecular interplay that characterizes the plasma membrane; understanding how cells continuously endocytose and exocytose materials across the cellular membrane; visualizing organelle trafficking; and, perhaps most importantly, monitoring the intracellular presence of target molecules such as nucleic acids, nutrients, cofactors, and ions or, alternatively, intracellular responses to external changes in the environment. We illustrate these processes with examples from the recent literature and focus on what QDs can uniquely contribute along with discussing the benefits and liabilities of each sensing strategy. A perspective on where this field is expected to develop in both the near and long-term is also provided.
doi_str_mv	10.1016/j.aca.2012.05.032
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Russ</creatorcontrib><creatorcontrib>Medintz, Igor L.</creatorcontrib><title>Active cellular sensing with quantum dots: Transitioning from research tool to reality; a review</title><title>Analytica chimica acta</title><addtitle>Anal Chim Acta</addtitle><description>[Display omitted] ► Quantum dots (QDs) have evolved beyond mere cellular labeling reagents. ► Significant advances have been made in QD materials, surface coatings and bioconjugation. ► Cellular targeting/delivery has been achieved using polymers, peptides, proteins. ► Numerous QD-based sensing applications: extracellular, membrane, intracellular. The application of luminescent semiconductor quantum dots (QDs) within a wide range of biological imaging and sensing formats is now approaching its 15th year. The unique photophysical properties of these nanomaterials have long been envisioned as having the potential to revolutionize biosensing within cellular studies that rely on fluorescence. However, it is only now that these materials are making the transition towards accomplishing this goal. With the idea of understanding how to actively incorporate QDs into different types of cellular biosensing, we review the progress in many of the areas relevant to achieving this goal. This includes the synthesis of the QDs themselves, with an emphasis on minimizing potential toxicity, along with the general methods for making these nanocrystalline structures stable in aqueous media. We next survey some methods for conjugating QDs to biomolecules to allow them to participate in active biosensing. Lastly, we extensively review many of the applications where QDs have been demonstrated in an active role in cellular biosensing. These formats cover a wide range of possibilities including where the QDs have contributed to: monitoring the cell's interaction with its extracellular environment; elucidating the complex molecular interplay that characterizes the plasma membrane; understanding how cells continuously endocytose and exocytose materials across the cellular membrane; visualizing organelle trafficking; and, perhaps most importantly, monitoring the intracellular presence of target molecules such as nucleic acids, nutrients, cofactors, and ions or, alternatively, intracellular responses to external changes in the environment. We illustrate these processes with examples from the recent literature and focus on what QDs can uniquely contribute along with discussing the benefits and liabilities of each sensing strategy. 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subjects	Analytical chemistry Animals Applied sciences Biological and medical sciences Biomolecules Biosensing Techniques Biosensor Biosensors Biotechnology Cell physiology Cell Tracking Cellular Chemistry Detection Endocytosis Exact sciences and technology Fluorescence Format Fundamental and applied biological sciences. Psychology Global environmental pollution Humans Imaging Ligands Membranes Methods. Procedures. Technologies Molecular and cellular biology Monitoring Peptides - chemistry Peptides - metabolism Pollution Polymers - chemistry Proteins - chemistry Proteins - metabolism Quantum dot Quantum Dots Semiconductors Silicon Dioxide - chemistry Spectrometric and optical methods Theranostics Various methods and equipments
title	Active cellular sensing with quantum dots: Transitioning from research tool to reality; a review
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