Nanomechanical force transducers for biomolecular and intracellular measurements: is there room to shrink and why do it?

Over the past couple of decades there has been a tremendous amount of progress on the development of ultrasensitive nanomechanical instruments, which has enabled scientists to peer for the first time into the mechanical world of biomolecular systems. Currently, work-horse instruments such as the ato...
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Autor*in:	Sirbuly, Donald J [verfasserIn] Friddle, Raymond W Villanueva, Joshua Huang, Qian

Format:	Artikel
Sprache:	Englisch

Erschienen:	2015

Schlagwörter:	Nanotechnology - methods DNA - chemistry Intracellular Space - physiology Nanotechnology - instrumentation Molecular Motor Proteins - chemistry

Übergeordnetes Werk:	Enthalten in: Reports on progress in physics - Bristol : IOP Publ., 1934, 78(2015), 2
Übergeordnetes Werk:	volume:78 ; year:2015 ; number:2

Links:	Link aufrufen

Katalog-ID:	OLC1967696810

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title_sort	nanomechanical force transducers for biomolecular and intracellular measurements: is there room to shrink and why do it?
title_auth	Nanomechanical force transducers for biomolecular and intracellular measurements: is there room to shrink and why do it?
abstract	Over the past couple of decades there has been a tremendous amount of progress on the development of ultrasensitive nanomechanical instruments, which has enabled scientists to peer for the first time into the mechanical world of biomolecular systems. Currently, work-horse instruments such as the atomic force microscope and optical/magnetic tweezers have provided the resolution necessary to extract quantitative force data from various molecular systems down to the femtonewton range, but it remains difficult to access the intracellular environment with these analytical tools as they have fairly large sizes and complicated feedback systems. This review is focused on highlighting some of the major milestones and discoveries in the field of biomolecular mechanics that have been made possible by the development of advanced atomic force microscope and tweezer techniques as well as on introducing emerging state-of-the-art nanomechanical force transducers that are addressing the size limitations presented by these standard tools. We will first briefly cover the basic setup and operation of these instruments, and then focus heavily on summarizing advances in in vitro force studies at both the molecular and cellular level. The last part of this review will include strategies for shrinking down the size of force transducers and provide insight into why this may be important for gaining a more complete understanding of cellular activity and function.
abstractGer	Over the past couple of decades there has been a tremendous amount of progress on the development of ultrasensitive nanomechanical instruments, which has enabled scientists to peer for the first time into the mechanical world of biomolecular systems. Currently, work-horse instruments such as the atomic force microscope and optical/magnetic tweezers have provided the resolution necessary to extract quantitative force data from various molecular systems down to the femtonewton range, but it remains difficult to access the intracellular environment with these analytical tools as they have fairly large sizes and complicated feedback systems. This review is focused on highlighting some of the major milestones and discoveries in the field of biomolecular mechanics that have been made possible by the development of advanced atomic force microscope and tweezer techniques as well as on introducing emerging state-of-the-art nanomechanical force transducers that are addressing the size limitations presented by these standard tools. We will first briefly cover the basic setup and operation of these instruments, and then focus heavily on summarizing advances in in vitro force studies at both the molecular and cellular level. The last part of this review will include strategies for shrinking down the size of force transducers and provide insight into why this may be important for gaining a more complete understanding of cellular activity and function.
abstract_unstemmed	Over the past couple of decades there has been a tremendous amount of progress on the development of ultrasensitive nanomechanical instruments, which has enabled scientists to peer for the first time into the mechanical world of biomolecular systems. Currently, work-horse instruments such as the atomic force microscope and optical/magnetic tweezers have provided the resolution necessary to extract quantitative force data from various molecular systems down to the femtonewton range, but it remains difficult to access the intracellular environment with these analytical tools as they have fairly large sizes and complicated feedback systems. This review is focused on highlighting some of the major milestones and discoveries in the field of biomolecular mechanics that have been made possible by the development of advanced atomic force microscope and tweezer techniques as well as on introducing emerging state-of-the-art nanomechanical force transducers that are addressing the size limitations presented by these standard tools. We will first briefly cover the basic setup and operation of these instruments, and then focus heavily on summarizing advances in in vitro force studies at both the molecular and cellular level. The last part of this review will include strategies for shrinking down the size of force transducers and provide insight into why this may be important for gaining a more complete understanding of cellular activity and function.
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container_issue	2
title_short	Nanomechanical force transducers for biomolecular and intracellular measurements: is there room to shrink and why do it?
url	http://www.ncbi.nlm.nih.gov/pubmed/25629797
remote_bool	false
author2	Friddle, Raymond W Villanueva, Joshua Huang, Qian
author2Str	Friddle, Raymond W Villanueva, Joshua Huang, Qian
ppnlink	129488356
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hochschulschrift_bool	false
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up_date	2024-07-04T01:42:27.583Z
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