Your search keyword '"Miao, Haichao"' showing total 4 results

1. Multiscale Visualization and Scale-Adaptive Modification of DNA Nanostructures.

Author

Miao H, De Llano E, Sorger J, Ahmadi Y, Kekic T, Isenberg T, Groller ME, Barisic I, and Viola I

Subjects

Models, Molecular, Semantics, Computer Graphics, DNA ultrastructure, Image Processing, Computer-Assisted methods, Nanostructures ultrastructure, Nanotechnology methods

Abstract

We present an approach to represent DNA nanostructures in varying forms of semantic abstraction, describe ways to smoothly transition between them, and thus create a continuous multiscale visualization and interaction space for applications in DNA nanotechnology. This new way of observing, interacting with, and creating DNA nanostructures enables domain experts to approach their work in any of the semantic abstraction levels, supporting both low-level manipulations and high-level visualization and modifications. Our approach allows them to deal with the increasingly complex DNA objects that they are designing, to improve their features, and to add novel functions in a way that no existing single-scale approach offers today. For this purpose we collaborated with DNA nanotechnology experts to design a set of ten semantic scales. These scales take the DNA's chemical and structural behavior into account and depict it from atoms to the targeted architecture with increasing levels of abstraction. To create coherence between the discrete scales, we seamlessly transition between them in a well-defined manner. We use special encodings to allow experts to estimate the nanoscale object's stability. We also add scale-adaptive interactions that facilitate the intuitive modification of complex structures at multiple scales. We demonstrate the applicability of our approach on an experimental use case. Moreover, feedback from our collaborating domain experts confirmed an increased time efficiency and certainty for analysis and modification tasks on complex DNA structures. Our method thus offers exciting new opportunities with promising applications in medicine and biotechnology.

Published

2018

2. Vivern–A Virtual Environment for Multiscale Visualization and Modeling of DNA Nanostructures.

Author

Kutak, David, Selzer, Matias Nicolas, Byska, Jan, Ganuza, Maria Lujan, Barisic, Ivan, Kozlikova, Barbora, and Miao, Haichao

Subjects

DNA nanotechnology, DNA folding, MULTISCALE modeling, VIRTUAL reality, DNA structure, TARGETED drug delivery, MOLECULAR motor proteins

Abstract

DNA nanostructures offer promising applications, particularly in the biomedical domain, as they can be used for targeted drug delivery, construction of nanorobots, or as a basis for molecular motors. One of the most prominent techniques for assembling these structures is DNA origami. Nowadays, desktop applications are used for the in silico design of such structures. However, as such structures are often spatially complex, their assembly and analysis are complicated. Since virtual reality (VR) was proven to be advantageous for such spatial-related tasks and there are no existing VR solutions focused on this domain, we propose Vivern, a VR application that allows domain experts to design and visually examine DNA origami nanostructures. Our approach presents different abstracted visual representations of the nanostructures, various color schemes, and an ability to place several DNA nanostructures and proteins in one environment, thus allowing for the detailed analysis of complex assemblies. We also present two novel examination tools, the Magic Scale Lens and the DNA Untwister, that allow the experts to visually embed different representations into local regions to preserve the context and support detailed investigation. To showcase the capabilities of our solution, prototypes of novel nanodevices conceptualized by our collaborating experts, such as DNA-protein hybrid structures and DNA origami superstructures, are presented. Finally, the results of two rounds of evaluations are summarized. They demonstrate the advantages of our solution, especially for scenarios where current desktop tools are very limited, while also presenting possible future research directions. [ABSTRACT FROM AUTHOR]

Published

2022

3. Vivern-A Virtual Environment for Multiscale Visualization and Modeling of DNA Nanostructures

Author

Kutak, David, Selzer, Matias Nicolas, Byska, Jan, Ganuza, Maria Lujan, Barisic, Ivan, Kozlikova, Barbora, and Miao, Haichao

Subjects

Computer science, MULTISCALE, Context (language use), 02 engineering and technology, Virtual reality, computer.software_genre, NANOSTRUCTURES, Domain (software engineering), purl.org/becyt/ford/1 [https], DNA ORIGAMI, NANOSCALE DEVICES, Human–computer interaction, ABSTRACTION, 0202 electrical engineering, electronic engineering, information engineering, Computer Graphics, DNA origami, DATA VISUALIZATION, THREE-DIMENSIONAL DISPLAYS, LATTICES, NANOTECHNOLOGY, Magic (programming), Proteins, 020207 software engineering, purl.org/becyt/ford/1.2 [https], DNA, Computer Graphics and Computer-Aided Design, Visualization, Nanostructures, MAGIC SCALE LENS, Virtual machine, FOCUS+CONTEXT, VIRTUAL REALITY, Signal Processing, VISUALIZATION, Nanorobotics, SOLID MODELING, Computer Vision and Pattern Recognition, IN SILICO MODELING, INTERACTION, computer, Software

Abstract

DNA nanostructures offer promising applications, particularly in the biomedical domain, as they can be used for targeted drug delivery, construction of nanorobots, or as a basis for molecular motors. One of the most prominent techniques for assembling these structures is DNA origami. Nowadays, desktop applications are used for the in silico design of such structures. However, as such structures are often spatially complex, their assembly and analysis are complicated. Since virtual reality (VR) was proven to be advantageous for such spatial-related tasks and there are no existing VR solutions focused on this domain, we propose Vivern, a VR application that allows domain experts to design and visually examine DNA origami nanostructures. Our approach presents different abstracted visual representations of the nanostructures, various color schemes, and an ability to place several DNA nanostructures and proteins in one environment, thus allowing for the detailed analysis of complex assemblies. We also present two novel examination tools, the Magic Scale Lens and the DNA Untwister, that allow the experts to visually embed different representations into local regions to preserve the context and support detailed investigation. To showcase the capabilities of our solution, prototypes of novel nanodevices conceptualized by our collaborating experts, such as DNA-protein hybrid structures and DNA origami superstructures, are presented. Finally, the results of two rounds of evaluations are summarized. They demonstrate the advantages of our solution, especially for scenarios where current desktop tools are very limited, while also presenting possible future research directions. Fil: Kutak, David. Masaryk University; República Checa Fil: Selzer, Matias Nicolas. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Bahía Blanca. Instituto de Ciencias e Ingeniería de la Computación; Argentina. Universidad Nacional del Sur. Departamento de Ciencias e Ingenieria de la Computacion. Laboratorio de Investigación y Desarrollo en Visualización yComputación Gráfica; Argentina Fil: Byska, Jan. Masaryk University; República Checa Fil: Ganuza, María Luján. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Bahía Blanca. Instituto de Ciencias e Ingeniería de la Computación; Argentina. Universidad Nacional del Sur. Departamento de Ciencias e Ingenieria de la Computacion. Laboratorio de Investigación y Desarrollo en Visualización yComputación Gráfica; Argentina Fil: Barisic, Ivan. Austrian Institute of Technology; Austria Fil: Kozlikova, Barbora. Masaryk University; República Checa Fil: Miao, Haichao. Austrian Institute of Technology; Austria

Published

2021

4. Unified Nanotechnology Format: One Way to Store Them All.

Author

Kuťák, David, Poppleton, Erik, Miao, Haichao, Šulc, Petr, and Barišić, Ivan

Subjects

NANOTECHNOLOGY, DNA structure, DNA nanotechnology, SOFTWARE development tools, NUCLEIC acids, DNA folding

Abstract

The domains of DNA and RNA nanotechnology are steadily gaining in popularity while proving their value with various successful results, including biosensing robots and drug delivery cages. Nowadays, the nanotechnology design pipeline usually relies on computer-based design (CAD) approaches to design and simulate the desired structure before the wet lab assembly. To aid with these tasks, various software tools exist and are often used in conjunction. However, their interoperability is hindered by a lack of a common file format that is fully descriptive of the many design paradigms. Therefore, in this paper, we propose a Unified Nanotechnology Format (UNF) designed specifically for the biomimetic nanotechnology field. UNF allows storage of both design and simulation data in a single file, including free-form and lattice-based DNA structures. By defining a logical and versatile format, we hope it will become a widely accepted and used file format for the nucleic acid nanotechnology community, facilitating the future work of researchers and software developers. Together with the format description and publicly available documentation, we provide a set of converters from existing file formats to simplify the transition. Finally, we present several use cases visualizing example structures stored in UNF, showcasing the various types of data UNF can handle. [ABSTRACT FROM AUTHOR]

Published

2022