Measuring Molecular Recognition Between Biomolecules with AFM-based Single-molecule Force Spectroscopy for Label-free Biosensing - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Measuring Molecular Recognition Between Biomolecules with AFM-based Single-molecule Force Spectroscopy for Label-free Biosensing write by Jingfeng Li. This book was released on 2019. Measuring Molecular Recognition Between Biomolecules with AFM-based Single-molecule Force Spectroscopy for Label-free Biosensing available in PDF, EPUB and Kindle.
Dynamic Force Spectroscopy and Biomolecular Recognition
Dynamic Force Spectroscopy and Biomolecular Recognition - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Dynamic Force Spectroscopy and Biomolecular Recognition write by Anna Rita Bizzarri. This book was released on 2012-01-25. Dynamic Force Spectroscopy and Biomolecular Recognition available in PDF, EPUB and Kindle. Molecular recognition, also known as biorecognition, is the heart of all biological interactions. Originating from protein stretching experiments, dynamic force spectroscopy (DFS) allows for the extraction of detailed information on the unbinding process of biomolecular complexes. It is becoming progressively more important in biochemical studies and is finding wider applications in areas such as biophysics and polymer science. In six chapters, Dynamic Force Spectroscopy and Biomolecular Recognition covers the most recent ideas and advances in the field of DFS applied to biorecognition: Chapter 1: Reviews the basic and novel aspects of biorecognition and discusses the emerging capabilities of single-molecule techniques to disclose kinetic properties and molecular mechanisms usually hidden in bulk measurements Chapter 2: Describes the basic principle of atomic force microsocopy (AFM) and DFS, with particular attention to instrumental and theoretical aspects more strictly related to the study of biomolecules Chapter 3: Overviews the theoretical background in which experimental data taken in nonequilibrum measurements of biomolecular unbinding forces are extrapolated to equilibrium conditions Chapter 4: Reviews the most common and efficient strategies adopted in DFS experiments to immobilize the interacting biomolecules to the AFM tip and to the substrate Chapter 5: Presents and discusses the most representative aspects related to the analysis of DFS data and the challenges of integrating well-defined criteria to calibrate data in automatic routinary procedures Chapter 6: Overviews the most relevant DFS applications to study biorecognition processes, including the biotin/avidin pair, and selected results on various biological complexes, including antigen/antibody, proteins/DNA, and complexes involved in adhesion processes Chapter 7: Summarizes the main results obtained by DFS applied to study biorecognition processes with forthcoming theoretical and experimental advances Although DFS is a widespread, worldwide technique, no books focused on this subject have been available until now. Dynamic Force Spectroscopy and Biomolecular Recognition provides the state of the art of experimental data analysis and theoretical procedures, making it a useful tool for researchers applying DFS to study biorecognition processes.
Investigation of Biomolecular Interactions for Development of Sensors and Diagnostics
Investigation of Biomolecular Interactions for Development of Sensors and Diagnostics - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Investigation of Biomolecular Interactions for Development of Sensors and Diagnostics write by Xiaojuan Zhang. This book was released on 2011. Investigation of Biomolecular Interactions for Development of Sensors and Diagnostics available in PDF, EPUB and Kindle. The highly specific recognition processes between biomolecules mediate various crucial biological processes. Uncovering the molecular basis of these interactions is of great fundamental and applied importance. This research work focuses on understanding the interactions of several biomolecular recognition systems and processes that can provide fundamental information to aid in the rational design of sensing and molecular recognition tools. Initially, a reliable and versatile platform was developed to investigate biomolecular interactions at a molecular level. This involved several techniques, including biomolecule functionalization to enable attachment to self-assembled monolayers as well as atomic force microscopy (AFM) based force spectroscopy to uncover the binding or rupture forces between the receptor and ligand pairs. It was shown that this platform allowed determination of molecular binding between single molecules with a high specificity. The platform was further adapted to a general sensing formulation utilizing a group of flexible and adaptive nucleic acid recognition elements (RNA and DNA aptamers) to detect specific target proteins. Investigation of interactions at the molecular level allowed characterization of the dynamics, specificity and the conformational properties of these functional nucleic acids in a manner inaccessible via traditional interaction studies. These interactions were then adapted to aptamer-based detecting methods that at the ensemble or bulk scale, specifically taking advantage of mechanisms uncovered in the biophysical study of this system. A quartz crystal microbalance (QCM) was used to detect protein targets at the bulk level and the affinities and binding kinetics of these systems were analyzed. Along with AFM-based force spectroscopy, ensemble-averaging properties and molecular properties of these interactions could be correlated to contribute to bridging the gap across length scales. Finally, more broadly applicable sensing platform was developed to take advantage of the unique properties of aptamers. DNA was employed both as a carrier and as a molecular recognition agent. DNA was used as a template for nanoconstruction and fabricating unique shapes that could enhance the aptamer-based molecular recognition strategies. With aptamers tagged to distinct nanoconstructed DNA, a novel shape-based detecting method was enabled at the molecular level. The results demonstrated that this is a flexible strategy, which can be further developed as ultrasensitive single molecule sensing strategy in complex environments.
Correlation Force Spectroscopy for Single Molecule Measurements
Correlation Force Spectroscopy for Single Molecule Measurements - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Correlation Force Spectroscopy for Single Molecule Measurements write by Milad Radiom. This book was released on 2015-03-30. Correlation Force Spectroscopy for Single Molecule Measurements available in PDF, EPUB and Kindle. This thesis addresses the development of a new force spectroscopy tool, correlation force spectroscopy (CFS) for the measurement of the properties of very small volumes of material (molecular to μm3) at kHz-MHz frequency range. CFS measures the simultaneous thermal fluctuations of two closely-spaced atomic force microscopy (AFM) cantilevers. CFS then calculates the cross-correlation in the thermal fluctuations that gives the mechanical properties of the matter that spans the gap of the two cantilevers. The book also discusses development of CFS, its advantages over AFM, and its application in single molecule force spectroscopy and micro-rheology.
Single Biomolecule Detection and Analysis
Single Biomolecule Detection and Analysis - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Single Biomolecule Detection and Analysis write by Tuhin Subhra Santra. This book was released on 2023-08-15. Single Biomolecule Detection and Analysis available in PDF, EPUB and Kindle. This collection discusses various micro/nanodevice design and fabrication for single-biomolecules detection. It will be an ideal reference text for graduate students and professionals in diverse subject areas including materials science, biomedical engineering, chemical engineering, mechanical engineering, and nanoscience. This book- Discusses techniques of single-biomolecule detection, their advantages, limitations, and applications. Covers comprehensively several electrochemical detection techniques. Provides single-molecule separation, sensing, imaging, sequencing, and analysis in detail. Examines different types of cantilever-based biomolecule sensing, and its limitations. Single Biomolecule Detection and Analysis covers single-biomolecule detection and characterization using micro/nanotechnologies and micro/nanofluidic devices, electrical and magnetic detection technologies, microscopy and spectroscopy techniques, single biomolecule optical, and nanopore devices. The text covers key important biosensors-based detection, stochastic optical reconstruction microscopy-based detection, electrochemical detection, metabolic engineering of animal cells, single-molecule intracellular delivery and tracking, terahertz spectroscopy-based detection, total internal reflection fluorescence (TIFR) detection, and Fluorescence Correlation Spectroscopy (FCS) detection. The text will be useful for graduate students and professionals in diverse subject areas including materials science, biomedical engineering, chemical engineering, mechanical engineering, and nanoscience. Discussing chemical process, physical process, separation, sensing, imaging, sequencing, and analysis of single-molecule detection, this text will be useful for graduate students and professionals in diverse subject areas including materials science, biomedical engineering, chemical engineering, mechanical engineering, and nanoscience. It covers microscopy and spectroscopy techniques for single-biomolecule detection, analysis, and their biomedical engineering applications.
