Lecture

DNA Origami: Nano Capsule Engineering

Related lectures (32)

Gene Editing and DNA Origami: Innovations in Biotechnology

Discusses recombinant DNA technology, CRISPR/Cas9 gene editing, and DNA origami applications in biotechnology.

Covers the basics of Chemical Engineering, including molecule manipulation, problem-solving areas, and material balances.

Supramolecular Chemistry: Molecular Machines and Motors

Delves into supramolecular chemistry, focusing on molecular machines and motors, exploring design principles and experimental support for controlled motion.

Zernike Phase-Contrast Imaging

Explores Zernike phase-contrast imaging, providing high-resolution images with high contrast for biological systems.

Electrochemical Interface Design

Discusses designing electrochemical interfaces for protein immobilization and implantable devices, exploring the concept of enhanced human beings through RFID microchips.

DNA Nanotechnology: Origami and Nanophotonics

Explores DNA origami nanotools for nanophotonics, focusing on light control at the nanoscale and the challenges in technological breakthroughs.

Nanotechnology: Fabrication and Imaging

Covers advanced lithography, nanoscale imaging, and fabrication techniques in nanotechnology.

Personalized Medicine: The Future of Healthcare

Delves into personalized medicine, showcasing recent technological advances and challenges in healthcare.

Molecular machines: Nature's nanotechnology

Explores nature's molecular machines, such as ATP synthase and DNA origami.

Engineering with DNA: Synthetic Assembly and Applications

Explores the engineering applications of synthetic DNA, including assembly techniques and versatile applications in lattices, crystals, drug delivery, and nano-robotics.

Self-organized growth at surfaces

Explores self-organized growth at surfaces and covers instrumentation, destructive exposure, manipulation with SIM, nanostructures, and thin film growth.

Imaging Electric Fields and Soft Matter: Multidimensional TEM

Explores imaging electric fields, 3D shapes, and soft matter using multidimensional TEM.

Introduction to Scaling Laws in Micro & Nanosystems

Covers scaling laws in micro & nanosystems, friction forces, electrical parameter scaling, molecular manufacturing accuracy, DNA origami, and CADNANO software.

Chemical Engineering Fundamentals

Covers the basics of Chemical Engineering, including material and energy balances, process classification, and system descriptions.

Self-assembly of Microsystems

Explores self-assembly of Microsystems, its importance, features, motivations, and examples in various fields, highlighting landmark achievements and future prospects.

Hierarchical Multi-scale Modeling of Molecular Systems

Explores the trends and challenges in modeling complex molecular systems using hierarchical multi-scale approaches, covering length-time scales, atomistic simulations, and force matching techniques.

Introduction to Advanced MEMS

Introduces the practical aspects of the Advanced MEMS course and explores MEMS technology, trends, sensors, actuators, and more.

NanoBioengineering Optical Sensors: SWCNTs & DNA Evolution

Delves into NanoBioengineering for optical sensors using SWCNTs and DNA evolution to enhance sensor performance and specificity.

Techno-scientific Promises: Challenges and Realities

Explores techno-scientific promises, societal impact, precision medicine, nanotechnology market trends, challenges of speculative bubbles, and ethical considerations.

Nano-Tera: Engineering the Future

Covers the Nano-Tera initiative, industrial impact proposals, funding, collaborative research for PhD students, and success stories.