Atomic Force Microscopy News and Research

RSS
Atomic force microscopy is a type of scanning probe microscopy used to image the surface of a substance, but at an atomic level. It can map the surface structure of different substances to understand how different structures interact with each other. This is done using a cantilever, which is similar to a vinyl record needle.
High-Speed Atomic Force Microscopy Reveals Cofilin Binding Patterns in Actin Filaments

High-Speed Atomic Force Microscopy Reveals Cofilin Binding Patterns in Actin Filaments

Plectasin's Velcro-Like Binding Holds Promise for Fighting Antimicrobial Resistance

Plectasin's Velcro-Like Binding Holds Promise for Fighting Antimicrobial Resistance

Groundbreaking Insights Into How Typical Perfluoroalkyl Acids Accelerate DNA Degradation

Groundbreaking Insights Into How Typical Perfluoroalkyl Acids Accelerate DNA Degradation

Model Helps Researchers 'See' Proteins on AFM Substrates

Model Helps Researchers 'See' Proteins on AFM Substrates

Kanazawa University Research: Researchers Define a Protocol for Narrow Cantilever Fabrication and High-Resolution Imaging of Living Cells Using AFM

Kanazawa University Research: Researchers Define a Protocol for Narrow Cantilever Fabrication and High-Resolution Imaging of Living Cells Using AFM

Innovative Technique Enables In Vivo Imaging of Intracellular Protein Aggregates

Innovative Technique Enables In Vivo Imaging of Intracellular Protein Aggregates

Exploring the Regulatory Mechanism and Physiological Significance of P62 Phosphorylation

Exploring the Regulatory Mechanism and Physiological Significance of P62 Phosphorylation

Hair Regrowth with Softening Stiff Hair Follicle Stem Cells with microRNA

Hair Regrowth with Softening Stiff Hair Follicle Stem Cells with microRNA

Researchers Uncover a New, Direction-Dependent Friction in Proteins

Researchers Uncover a New, Direction-Dependent Friction in Proteins

Fiber optical nanomechanical probe can measure in vivo biomechanical properties of tissue, single cell

Fiber optical nanomechanical probe can measure in vivo biomechanical properties of tissue, single cell

Intracellular drug delivery using a novel nano transporter

Intracellular drug delivery using a novel nano transporter

Potential SARS-CoV-2 therapy based on banana protein

Potential SARS-CoV-2 therapy based on banana protein

New insights into cadherin binding using high-speed atomic force microscopy

New insights into cadherin binding using high-speed atomic force microscopy

Experts determine the assembly of proteins with specialized protein needles

Experts determine the assembly of proteins with specialized protein needles

Improving our Understanding of Bacterial Membranes

Improving our Understanding of Bacterial Membranes

Novel technique greatly increases the resolution of atomic force microscopy

Novel technique greatly increases the resolution of atomic force microscopy

First real-time observation of DNA-histone interactions

First real-time observation of DNA-histone interactions

Supercomputer simulations help uncover the mechanism for HIV replication

Supercomputer simulations help uncover the mechanism for HIV replication

New atomic force microscopy enables faster, less-invasive imaging of biological samples

New atomic force microscopy enables faster, less-invasive imaging of biological samples

Altered sugar composition impacts cell-to-surface adhesion

Altered sugar composition impacts cell-to-surface adhesion

While we only use edited and approved content for Azthena answers, it may on occasions provide incorrect responses. Please confirm any data provided with the related suppliers or authors. We do not provide medical advice, if you search for medical information you must always consult a medical professional before acting on any information provided.

Your questions, but not your email details will be shared with OpenAI and retained for 30 days in accordance with their privacy principles.

Please do not ask questions that use sensitive or confidential information.

Read the full Terms & Conditions.