Self-Assembled Monolayers as Platforms for Nanobiotechnology and Biointerface Research: Fabrication, Analysis, Mechanisms, and Design
T. Hayashi, Glenn Villena Latag
Abstract
High Resolution Image Download MS PowerPoint Slide Self-assembled monolayers (SAMs) have revolutionized how we modify and control surface properties at the molecular level. Since the first report in the 1980s, these nanoscale coatings have found widespread applications in biosensing, nanobiotechnology, and molecular electronics, offering precise control over surface chemistry, wettability, and bioactivity. This review explores the fundamental principles behind SAMs, detailing their structure, fabrication techniques, and characterization methods. We also examine the various analytical tools used to study SAMs and their interactions with biological molecules, particularly in the context of protein adsorption and cell adhesion. Special attention is given to the role of SAMs in biosensing and biointerfaces, where they enable the development of biomaterials designed to influence cellular behavior in particular ways. Beyond experimental advances, we highlight the growing impact of materials informatics and machine learning in SAM research. These informatics approaches transform how SAMs are designed, allowing researchers to predict optimal molecular configurations for targeted applications. Finally, we address key challenges in the field and discuss the prospects of SAM technologies, including their potential for commercialization. As SAM research continues to evolve, its synergy with emerging technologies promises exciting possibilities for biomedical and electronic applications.