For more details on the courses, please refer to the Course Catalog
Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
---|---|---|---|---|---|---|---|---|---|
IPH5028 | 3D printed chip design and fabrication. | 3 | 6 | Major | Master/Doctor | Intelligent Precision Healthcare Convergence | English | Yes | |
The main objective of the course is to introduce 3D bioprinting used in lab-on-chips to graduate students having a background in engineering. The course should familiarize the students with the techniques used in 3D bioprinting and show them how 3D printing technology pervades throughout various regenerative medicine. 3D bio-/nonbio- printing techniques, biomaterials, cell culture will be reviewed. Students will perform laboratory exercises designed to (1) design, model 3D printed chip, (2) manufacture, use 3D printed chips in experiments. | |||||||||
IPH5029 | Stem cell engineering in precision medicine | 3 | 6 | Major | Master/Doctor | Intelligent Precision Healthcare Convergence | - | No | |
Stem cell plays pivotal roles in maintaining functionality of various organs in our body through self-renew, proliferation and differentiation. It has been highlighted as a key factor in the development of biomedical applications such as cell therapy and drug screening. This class mainly aims to understand and discuss about stem cells and their applications in precision medicine and regenerative medicine. | |||||||||
IPH5030 | precision medicine in brain aging and dementia | 3 | 6 | Major | Master/Doctor | Intelligent Precision Healthcare Convergence | - | No | |
Due to the recent increase in the elderly population, interest in brain aging and dementia is gradually increasing. In particular, it is possible to predict them through biomarkers or brain images, and the accuracy is further increased with the development of artificial intelligence technology. On the other hand, with the development of genome analysis, it has become possible to develop individualized prediction algorithms for each individual. Through these lectures, I will cover following subjects: 1) general concepts of brain aging and dementia, 2) biomarkers of brain aging and dementia and development of brain imaging technology, 3) clinical application of artificial intelligence technology to brain aging and dementia, and 4) genomic technology. | |||||||||
IPH5031 | Practice on Optimization of Biomedical Systems | 3 | 6 | Major | Master/Doctor | Intelligent Precision Healthcare Convergence | - | No | |
This lecture is designed to address the needs or questions raised from real industries or academia. During the class, only high level subjects about the optimization of medical systems will be suggested, and the detail goal and plans will be come out of brainstorm as a team. And then students should find solutions to address the explored problems came out of the discussions and needs to submit the final reports structured like a peer-reviewed research paper. | |||||||||
IPH5032 | Nanophotonics and Its Biomedical Applications | 3 | 6 | Major | Master/Doctor | Intelligent Precision Healthcare Convergence | English | Yes | |
In this lecture, we will learn theoretical knowledge related to the interaction of light and nanomaterials and its biomedical application technology. Specifically, after learning the basics related to optics, electromagnetism, and quantum mechanics, we will deal with various topics such as quantum emitters, photonic crystals, surfaces plasmons, and metamaterials. In addition, biomedical application technologies such as optical microscopy, spectroscopy, and nanobiosensor using each technology will be introduced. | |||||||||
IPH5033 | Plasmonics and Metamaterials for Biomedical Applications | 3 | 6 | Major | Master/Doctor | Intelligent Precision Healthcare Convergence | English | Yes | |
In this lecture, we will discuss the latest nano-optical technologies using plasmonics and metamaterials and their biomedical application technologies. Specifically, we want to learn about the principles and optical properties of plasmonic nanostructures and metamaterials, and learn surface enhancement sensing technology, super-resolution microscopy technology, and unconventional nano-biosensor technology. In addition, we will briefly discuss the device design methodologies and nanofabricaiton techniques for practical implementation. | |||||||||
IPH5034 | Neuro-electronics system | 3 | 6 | Major | Master/Doctor | Intelligent Precision Healthcare Convergence | English | Yes | |
This course introduces neuro-electronics system. The goal of this course is to provide basic knowledge to students who are interested in designing electronic system interacting with human nervous system and human body. First, students will learn the generation/propagation of action potential and operation principles of human nervous/muscular/skeletal systems. Second, students will learn the whole design process of the neuro-electronics system that can communicate with the nervous system and assist/replace/augment body functions. | |||||||||
IPH5035 | Current topics in computational psychiatry | 3 | 6 | Major | Master/Doctor | Intelligent Precision Healthcare Convergence | English | Yes | |
This class is designed to introduce graduate students a recently emerging new field called ‘computational neuropsychiatry’, and mainly to educate the students to have a real sense how to bridge between neuroscience and the practical clinical fields. In particular, it aims at introducing trends in various topics regarding to theoretical models, computational approaches and research designs at the junction between cognitive and clinical neurosciences. It will also provide several important applications how the big data science and machine learning techniques have recently shape to advance this field. This class will proceed a periodical and interleaved course system between an instructor’s lecture for background introduction and graduate student’s presentation of seminal papers. This design is to maximize both a trainee’s understanding level of domain-specific knowledge and dicussion participation. The class will be an absolute grading system, determined by a peer-reviewed formal presentation (1 time per semester) as well as class participation. | |||||||||
IPH7001 | Ultrasound transducers for precise medicine | 3 | 6 | Major | Bachelor/Master/Doctor | Intelligent Precision Healthcare Convergence | English | Yes | |
This lecture is about the basic theory of operations, structures, fabrication skills on ultrasonic transducers. Through this lecture, students will have insights on not only the principles about the acoustic transducers and the physics of piezoelectric materials, but also the optimizations of the structures and schematics of the ultrasonic transducers. The contents of this lecture covers the physics on ultrasound and piezoelectric materials, the schematics and operations of ultrasonic transducers and the simulation programs. | |||||||||
IPH7002 | Ultrasound imaging for precise medicine | 3 | 6 | Major | Bachelor/Master/Doctor | Intelligent Precision Healthcare Convergence | English | Yes | |
This lecture is about the basic theory of operations on ultrasonic imaging and techniques. Through this lecture, students will have insights on enhancing ultrasonic image qualities through engineering the systems and physical parameters. Also, the students may expand their research territories to the ultrasonic technologies converging with their own specialties. During the lecture, ultrasonic physics, B-Mode, Color-mode, Doppler mode imaging skills will be dealt with, and a text book on ‘essential of ultrasonic physics’ will be employed for the presentations to deepen and broaden the understanding on ultrasound imaging. | |||||||||
IPH7003 | Intelligent Precision Healthcare Convergence Seminar | 3 | 6 | Major | Bachelor/Master/Doctor | 1-8 | Intelligent Precision Healthcare Convergence | English | Yes |
This lecture is to provide graduate students fundamental concepts and applications in the following three special research areas: Intelligent bioinformation, Intelligent biomarker and analysis, Intelligent targetted therapy and artificial body. Based on these concepts in the three specialized fields, we will deal with future technical applications, pathological disease and clinical applications, industry applications. | |||||||||
IPH7004 | Technical Writing for Research Papers | 3 | 6 | Major | Bachelor/Master/Doctor | Intelligent Precision Healthcare Convergence | English | Yes | |
The purpose of the course is to understand how research papers are constructed and acquire technical skills for writing them. Combination of lectures and practices - Structures of papers and writing skills - case studies - exercise of writing mockup papers with any topics | |||||||||
IPH7005 | Intelligent Bio Convergence Seminar | 3 | 6 | Major | Bachelor/Master/Doctor | Intelligent Precision Healthcare Convergence | English | Yes | |
This lecture is to expose both undergraduate and graduate students to artificial intelligene and its applications. To this end, this seminar lecture includes brain science and neural mechanism, neuroscience based artificial intelligence, construction of big training data for AI, AI applications for precision medicine, etc. | |||||||||
IPH7006 | advanced decision making 2 | 3 | 6 | Major | Bachelor/Master/Doctor | Intelligent Precision Healthcare Convergence | English | Yes | |
In this class, we learn journal papers studying the neural mechanisms of decision making using animal models. Each week, we read papers from the same laboratory, investigating the same topic. By this, we may have a chance to appreciate what is it like to ask a serious of questions to understand underlying mechanisms. | |||||||||
IPH7007 | Introduction to Photonics | 3 | 6 | Major | Bachelor/Master/Doctor | Intelligent Precision Healthcare Convergence | English | Yes | |
This introductory optical engineering class aims to improve the basic knowledge of the field of optics and the understanding of various application technologies utilizing it for students in the Intelligent Precision Healthcare Convergence major. To this end, in this lecture, you will learn basic theories related to 1) ray optics, 2) wave optics, 3) diffraction optics, 4) Fourier optics, 5) electromagnetic optics, 6) waveguide optics. Also, we plan to study application technologies such as 7) light-matter interaction, 8) laser, 9) semiconductor optics, 10) acoustic optics, 11) electro-optics, and 12) nonlinear optics. |