The natural, biological, medical, and related sciences would not be what they are today without the microscope. After the introduction of the optical microscope, a second breakthrough in morphostructural surface analysis occurred in the 1940s with the development of the scanning electron microscope (SEM), which, instead of light (i. e. , photons) and glass lenses, uses electrons and electromagnetic lenses (magnetic coils). Optical and scanning (or transmission) electron microscopes are called "far-field microscopes" because of the long distance between the sample and the point at which the image is obtained in comparison with the wavelengths of the photons or electrons involved. In this case, the image is a diffraction pattern and its resolution is wavelength limited. In 1986, a completely new type of microscopy was proposed, which, without the use of lenses, photons, or electrons, directly explores the sample surface by means of mechanical scanning, thus opening up unexpected possibilities for the morphostructural and mechanical analysis of biological specimens. These new scanning probe microscopes are based on the concept of near-field microscopy, which overcomes the problem of the limited diffraction-related resolution inherent in conventional microscopes. Located in the immediate vicinity of the sample itself (usually within a few nanometers), the probe records the intensity, rather than the interference signal, thus significantly improving resolution. Since the most we- known microscopes of this type operate using atomic forces, they are frequently referred to as atomic force microscopes (AFMs).

With its ability to explore the surface of the sample by means of a local scanning probe and its use of dedicated software allows to be visualize results, atomic force microscopy (AFM) has revolutionized the study of the smallest aspects of life. Atomic Force Microscopy in Biomedical Research: Methods and Protocols proves that this technology is no longer simply just another form of microscopy but has given rise to a completely new way of using microscopy that fulfils the dreams of all microscopists: being able to touch, move, and interact with the sample while it is being examined, thus making it possible to discover not only morphological but also chemical and physical structural information. Covering such topics as molecule imaging, nanoscale surface analysis and cellular imaging, force-spectroscopy, investigating drug action, and AFM as a nanotool, this volume features the most up-to-date techniques currently in use. Written in the Methods in Molecular Biology (TM) series format, chapters include introductions to their respective topics, lists of the necessary materials, step-by-step, readily reproducible protocols, and expert tips on troubleshooting and avoiding known pitfalls. Comprehensive and cutting-edge, Atomic Force Microscopy in Biomedical Research: Methods and Protocols brings together different types of applications in order to provide examples from diverse fields in the hope of inspiring researchers to apply their ingenuity in their own specialization and add significant originality to their varying studies.

The natural, biological, medical, and related sciences would not be what they are today without the microscope. After the introduction of the optical microscope, a second breakthrough in morphostructural surface analysis occurred in the 1940s with the development of the scanning electron microscope (SEM), which, instead of light (i. e. , photons) and glass lenses, uses electrons and electromagnetic lenses (magnetic coils). Optical and scanning (or transmission) electron microscopes are called "far-field microscopes" because of the long distance between the sample and the point at which the image is obtained in comparison with the wavelengths of the photons or electrons involved. In this case, the image is a diffraction pattern and its resolution is wavelength limited. In 1986, a completely new type of microscopy was proposed, which, without the use of lenses, photons, or electrons, directly explores the sample surface by means of mechanical scanning, thus opening up unexpected possibilities for the morphostructural and mechanical analysis of biological specimens. These new scanning probe microscopes are based on the concept of near-field microscopy, which overcomes the problem of the limited diffraction-related resolution inherent in conventional microscopes. Located in the immediate vicinity of the sample itself (usually within a few nanometers), the probe records the intensity, rather than the interference signal, thus significantly improving resolution. Since the most we- known microscopes of this type operate using atomic forces, they are frequently referred to as atomic force microscopes (AFMs).

With its ability to explore the surface of the sample by means of a local scanning probe and its use of dedicated software allows to be visualize results, atomic force microscopy (AFM) has revolutionized the study of the smallest aspects of life. Atomic Force Microscopy in Biomedical Research: Methods and Protocols proves that this technology is no longer simply just another form of microscopy but has given rise to a completely new way of using microscopy that fulfils the dreams of all microscopists: being able to touch, move, and interact with the sample while it is being examined, thus making it possible to discover not only morphological but also chemical and physical structural information. Covering such topics as molecule imaging, nanoscale surface analysis and cellular imaging, force-spectroscopy, investigating drug action, and AFM as a nanotool, this volume features the most up-to-date techniques currently in use. Written in the Methods in Molecular Biology (TM) series format, chapters include introductions to their respective topics, lists of the necessary materials, step-by-step, readily reproducible protocols, and expert tips on troubleshooting and avoiding known pitfalls. Comprehensive and cutting-edge, Atomic Force Microscopy in Biomedical Research: Methods and Protocols brings together different types of applications in order to provide examples from diverse fields in the hope of inspiring researchers to apply their ingenuity in their own specialization and add significant originality to their varying studies.