Single cell analysis inside Environmental Scanning Electron Microscope (ESEM)-nanomanipulator system

The conventional approach to characterize cellular biology is called biochemistry. This developed science is used for studying physiological aspects, mainly genetics, by characterizing protein and other biomaterials. Since single cells are difficult to study, a collection of cells are used for ch...

Full description

Saved in:
Bibliographic Details
Main Authors: Ahmad, Mohd. Ridzuan, Nakajima, Masahiro, Kojima, Seiji, Homma, Michio, Fukuda, Toshio
Other Authors: Dragica, Vasileska
Format: Book Section
Published: In-Teh 2010
Subjects:
Online Access:http://eprints.utm.my/id/eprint/31179/
http://dx.doi.org/10.5772/8858
Tags: Add Tag
No Tags, Be the first to tag this record!
id my.utm.31179
record_format eprints
spelling my.utm.311792017-08-03T01:02:53Z http://eprints.utm.my/id/eprint/31179/ Single cell analysis inside Environmental Scanning Electron Microscope (ESEM)-nanomanipulator system Ahmad, Mohd. Ridzuan Nakajima, Masahiro Kojima, Seiji Homma, Michio Fukuda, Toshio TK Electrical engineering. Electronics Nuclear engineering The conventional approach to characterize cellular biology is called biochemistry. This developed science is used for studying physiological aspects, mainly genetics, by characterizing protein and other biomaterials. Since single cells are difficult to study, a collection of cells are used for characterizing cellular physiology and inturn used to describe behavior of single cell (Brehm-Stecher & Johson, 2004). However, in addition to this advance understanding of cellular genetics, information about mechanical properties of cells is also needed. The molecular structure of the cell-wall is only partially understood, and its mechanical properties are an area of “near-total darkness” (Harold, 2005). Moreover, the approximation of single cell behavior from a group used in conventional approach also requires further justification whether it can be applied to all cell types (Shapiro, 2000). The knowledge of the cell mechanics could be valuable in the future for biomedical applications, for example, variations in cell mechanics of healthy and unhealthy cells can be linked to a specific disease. Available experimental techniques to probe single cells include micropipette aspiration, optical tweezers, magnetic tweezers (Bausch et al., 1999), atomic/molecular force probes (Gueta et al., 2006), nanoindenters, microplate manipulators, optical stretchers (Thoumine et al., 1999) and nanoneedle (Obataya et al., 2005).. The functionality of nanoneedles is not limited only to the stiffness measurements but it can also be used for single cell surgery (Leary et al., 2006) which can be further applied to a novel single cell drug delivery system (Bianco et al., 2005) or as a delivery tool for nanoparticles (Brigger et al., 2002). Conventional drug therapy suffers from the problems of inefficacy or nonspecific effects; hence, nanosystems are being developed for targeted drug delivery (Stylios et al., 2005). In order to successfully deliver materials; e.g. bioactive peptide, proteins, nucleic acids or drugs inside the cell, carriers must be able to penetrate the cell wall or cell membrane without causing death or create any mechanotransduction to the cell (Goodman et al., 2004), i.e. the process of converting physical forces to biochemical signals and integrating them into cellular responses (Huang et al., 2004). Therefore, the knowledge of biomechanics of the cell is crucial in providing prior-estimation of required insertion force to deliver drug material inside the cell. Without having this information, the insertion process may be unsuccessful due to inadequate applied force or the cell may be seriously damaged due to the excessive applied force. This chapter focuses on the following two needs, i.e. the needs for the understanding of the mechanical properties of single cells and the needs for the novel nanotools for the single cells probing. The first need was fed by highlighting our findings on the effects of three factors, i.e. cell sizes, environmental conditions and growth phases, on the strength of the single W303 yeast cells. The second need was served by showing our findings on the development of nanoneedles which can be used for single cell local stiffness characterizations and single cell surgery. In-Teh Dragica, Vasileska 2010-03-01 Book Section PeerReviewed Ahmad, Mohd. Ridzuan and Nakajima, Masahiro and Kojima, Seiji and Homma, Michio and Fukuda, Toshio (2010) Single cell analysis inside Environmental Scanning Electron Microscope (ESEM)-nanomanipulator system. In: Cutting Edge Nanotechnology. In-Teh, Vukovar, Croatia, pp. 413-438. ISBN 978-953-7619-93-0 http://dx.doi.org/10.5772/8858 DOI: 10.5772/8858
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
topic TK Electrical engineering. Electronics Nuclear engineering
spellingShingle TK Electrical engineering. Electronics Nuclear engineering
Ahmad, Mohd. Ridzuan
Nakajima, Masahiro
Kojima, Seiji
Homma, Michio
Fukuda, Toshio
Single cell analysis inside Environmental Scanning Electron Microscope (ESEM)-nanomanipulator system
description The conventional approach to characterize cellular biology is called biochemistry. This developed science is used for studying physiological aspects, mainly genetics, by characterizing protein and other biomaterials. Since single cells are difficult to study, a collection of cells are used for characterizing cellular physiology and inturn used to describe behavior of single cell (Brehm-Stecher & Johson, 2004). However, in addition to this advance understanding of cellular genetics, information about mechanical properties of cells is also needed. The molecular structure of the cell-wall is only partially understood, and its mechanical properties are an area of “near-total darkness” (Harold, 2005). Moreover, the approximation of single cell behavior from a group used in conventional approach also requires further justification whether it can be applied to all cell types (Shapiro, 2000). The knowledge of the cell mechanics could be valuable in the future for biomedical applications, for example, variations in cell mechanics of healthy and unhealthy cells can be linked to a specific disease. Available experimental techniques to probe single cells include micropipette aspiration, optical tweezers, magnetic tweezers (Bausch et al., 1999), atomic/molecular force probes (Gueta et al., 2006), nanoindenters, microplate manipulators, optical stretchers (Thoumine et al., 1999) and nanoneedle (Obataya et al., 2005).. The functionality of nanoneedles is not limited only to the stiffness measurements but it can also be used for single cell surgery (Leary et al., 2006) which can be further applied to a novel single cell drug delivery system (Bianco et al., 2005) or as a delivery tool for nanoparticles (Brigger et al., 2002). Conventional drug therapy suffers from the problems of inefficacy or nonspecific effects; hence, nanosystems are being developed for targeted drug delivery (Stylios et al., 2005). In order to successfully deliver materials; e.g. bioactive peptide, proteins, nucleic acids or drugs inside the cell, carriers must be able to penetrate the cell wall or cell membrane without causing death or create any mechanotransduction to the cell (Goodman et al., 2004), i.e. the process of converting physical forces to biochemical signals and integrating them into cellular responses (Huang et al., 2004). Therefore, the knowledge of biomechanics of the cell is crucial in providing prior-estimation of required insertion force to deliver drug material inside the cell. Without having this information, the insertion process may be unsuccessful due to inadequate applied force or the cell may be seriously damaged due to the excessive applied force. This chapter focuses on the following two needs, i.e. the needs for the understanding of the mechanical properties of single cells and the needs for the novel nanotools for the single cells probing. The first need was fed by highlighting our findings on the effects of three factors, i.e. cell sizes, environmental conditions and growth phases, on the strength of the single W303 yeast cells. The second need was served by showing our findings on the development of nanoneedles which can be used for single cell local stiffness characterizations and single cell surgery.
author2 Dragica, Vasileska
author_facet Dragica, Vasileska
Ahmad, Mohd. Ridzuan
Nakajima, Masahiro
Kojima, Seiji
Homma, Michio
Fukuda, Toshio
format Book Section
author Ahmad, Mohd. Ridzuan
Nakajima, Masahiro
Kojima, Seiji
Homma, Michio
Fukuda, Toshio
author_sort Ahmad, Mohd. Ridzuan
title Single cell analysis inside Environmental Scanning Electron Microscope (ESEM)-nanomanipulator system
title_short Single cell analysis inside Environmental Scanning Electron Microscope (ESEM)-nanomanipulator system
title_full Single cell analysis inside Environmental Scanning Electron Microscope (ESEM)-nanomanipulator system
title_fullStr Single cell analysis inside Environmental Scanning Electron Microscope (ESEM)-nanomanipulator system
title_full_unstemmed Single cell analysis inside Environmental Scanning Electron Microscope (ESEM)-nanomanipulator system
title_sort single cell analysis inside environmental scanning electron microscope (esem)-nanomanipulator system
publisher In-Teh
publishDate 2010
url http://eprints.utm.my/id/eprint/31179/
http://dx.doi.org/10.5772/8858
_version_ 1643648686115258368
score 13.211869