Presentation is loading. Please wait.

Presentation is loading. Please wait.

Biophysics Division -1- Biophysics Division Cellular/Molecular Imaging for Bonghan System Study 2006. 9. 27. Kwang-Sup Soh Biomedical Physics Lab. for.

Published byJalyn Siner Modified over 9 years ago

Similar presentations

Presentation on theme: "Biophysics Division -1- Biophysics Division Cellular/Molecular Imaging for Bonghan System Study 2006. 9. 27. Kwang-Sup Soh Biomedical Physics Lab. for."— Presentation transcript:

1 Biophysics Division -1- Biophysics Division Cellular/Molecular Imaging for Bonghan System Study 2006. 9. 27. Kwang-Sup Soh Biomedical Physics Lab. for Korean Medicine School of Physics, Seoul National University

2 Biophysics Division -2- Contents I. Introduction on Bonghan System II. Co-operative Research Progress (1)Electron Microscope (2)Atomic Force Microscope (3)Nanoparticles

3 Biophysics Division I. Bonghan System

4 Biophysics Division -4- Bonghan System Organ-Surface BH duct (on the surface of organs) (on the surface of organs) Superficial BH duct (Acupuncture meridian) Superficial BH Corpuscle (Acupoints) skin : superficial BH ducts skin : superficial BH ducts network surface of organs : OSBHD network surface of organs : OSBHD inside vessels : intra-vascular BHD inside vessels : intra-vascular BHD Intravascular BH duct

5 Biophysics Division -5- Physiological Significance New Circulation System  Hyaluronic acid, Amino acid, Mono nucleotide,  Hormone: Adrenalin/noradrenalin Bonghan Granules (Ф≈0.8~2.4μm) containing DNA  Adult stem cells: cell therapy  Natural “micro-cell”: gene therapy

6 Biophysics Division II. Research Progress

7 Biophysics Division -7- Future Prospects AnatomyPhysiology Electron Microscopes AFMNanobiotechnology Optical Tweezer 2005 Sept, CKC Symposium

8 Biophysics Division -8- Electron Microscopes Microscopy Research & Technology, 2006 Electron Microscopic Study of Novel Threadlike Structures on the Surfaces of Mammalian Organs Byung-Cheon Lee, 1 Jung Sun Yoo, 1 Vyacheslav Ogay, 1 Ki Woo Kim, 2 Harald Dobberstein, 3 Kwang-Sup Soh, 1, † and Byung-Soo Chang 4, † 1 Biomedical Physics Laboratory, FPRD, School of Physics and Astronomy, Seoul National University, Seoul, Korea 2 National Instrumentation Center for Environmental Management, College of Agriculture and Life Sciences, Seoul National University, Seoul, Korea 3 Department of Physics, Cavendish Laboratory, University of Cambridge, Cambridge, CB3 0HE, UK 4 Department of Cosmetology, Hanseo University, Seosan, Korea

9 Biophysics Division -9- Electron Microscopes Fig.1. Stereomicroscopic Images of novel threadlike structures

10 Biophysics Division -10- Electron Microscopes SEM

11 Biophysics Division -11- Electron Microscopes TEM

12 Biophysics Division -12- Electron Microscopes Cryo-SEM FIB/SEM (Cavendish)

13 Biophysics Division -13- Atomic Force Microscope Investigation of morphology and physical properties of Bonghan microcell using AFM and TEM 1 Ku Youn Baik, 1 Joonhyung Kwon, 1 Byung –Cheon Lee, 2 Harald Dobberstein, and 1 Kwang-Sup Soh $ 1 Biomedical Physics Laboratory, Department of Physics, Seoul National University, Seoul, 151-747, Korea 2 Cavendish Laboratory, University of Cambridge, Cambridge, CB3 0HE, UK - 2006.7.2 - 7 Molecular Cell Biology GRC, NH, USA Microcell-like granules in the Bonghan corpuscle on the surfaces of mammalian internal organs 1 Ku Youn Baik, 1 Vyacheslav Ogay, 2 Harald Dobberstein, and 1 Kwang-Sup Soh 1 Biomedical Physics Laboratory, Department of Physics, Seoul National University, Seoul, 151-747, Korea 2 Cavendish Laboratory, University of Cambridge, Cambridge, CB3 0HE, UK - 2006.8.27 WC2006 Conference, Seoul, Korea

14 Biophysics Division -14- Atomic Force Microscope Bonghan microcell cycle (Bonghan Kim, 1965) (1) All the morphological components of organism are ceaselessly reproduced. (2) The self-reproduction of organism takes the form of Bonghan microcell-cell cycles. (3) The self-reproduction of organism is performed by the acupuncture-meridian system. Theory of Bonghan Microcell

15 Biophysics Division -15- A Topography, B Error, C Magnified of B, D line profile 1.4 um x 1um x 350nm sized oval Bonghan microcell. It shows clearly unique surface structure of layers and portions (B & C) whose size is from 0.2um to 0.6 um in diameter. The line profile analysis shows that the common patterns on the surface are steps of about 20nm height. This pattern is thought to be revealing the stereotype of its membrane structure. AFM image of Bonghan microcell 20nm A B C D

16 Biophysics Division -16- Nanobiotechnology Flowing Channel of Nanoparticles

Download ppt "Biophysics Division -1- Biophysics Division Cellular/Molecular Imaging for Bonghan System Study 2006. 9. 27. Kwang-Sup Soh Biomedical Physics Lab. for."

Similar presentations

TWO STEP EQUATIONS 1. SOLVE FOR X 2. DO THE ADDITION STEP FIRST

TWO STEP EQUATIONS 1. SOLVE FOR X 2. DO THE ADDITION STEP FIRST
Chemical named entity recognition and literature mark-up Colin Batchelor Informatics Department Royal Society of Chemistry

Chemical named entity recognition and literature mark-up Colin Batchelor Informatics Department Royal Society of Chemistry
How To Organize Your Binder: Nature of Science Unit

How To Organize Your Binder: Nature of Science Unit
Mrs. Samina Anwar Grade 9 April 2011 - March 2012.

Mrs. Samina Anwar Grade 9 April March 2012.
§ 1.10 Properties of the Real Number System. Angel, Elementary Algebra, 7ed 2 Commutative Property Commutative Property of Addition If a and b represent.

§ 1.10 Properties of the Real Number System. Angel, Elementary Algebra, 7ed 2 Commutative Property Commutative Property of Addition If a and b represent.
Scanning near-field optical microscopy (SNOM) for magneto-optics Paolo Vavassori INFM - National Research Center on nanoStructures and Biosystems at Surfaces.

Scanning near-field optical microscopy (SNOM) for magneto-optics Paolo Vavassori INFM - National Research Center on nanoStructures and Biosystems at Surfaces.
Slide 1 Insert your own content. Slide 2 Insert your own content.

Slide 1 Insert your own content. Slide 2 Insert your own content.
Chapter 1 The Study of Body Function Image PowerPoint

Chapter 1 The Study of Body Function Image PowerPoint
1 Copyright © 2011, Elsevier Inc. All rights Reserved. Size Analysis and Identification of Particles Chapter 4 Roger W. Welker.

1 Copyright © 2011, Elsevier Inc. All rights Reserved. Size Analysis and Identification of Particles Chapter 4 Roger W. Welker.
1 Copyright © 2010, Elsevier Inc. All rights Reserved Fig 2.1 Chapter 2.

1 Copyright © 2010, Elsevier Inc. All rights Reserved Fig 2.1 Chapter 2.
1 Chapter 40 - Physiology and Pathophysiology of Diuretic Action Copyright © 2013 Elsevier Inc. All rights reserved.

1 Chapter 40 - Physiology and Pathophysiology of Diuretic Action Copyright © 2013 Elsevier Inc. All rights reserved.
Jeopardy Q 1 Q 6 Q 11 Q 16 Q 21 Q 2 Q 7 Q 12 Q 17 Q 22 Q 3 Q 8 Q 13

Jeopardy Q 1 Q 6 Q 11 Q 16 Q 21 Q 2 Q 7 Q 12 Q 17 Q 22 Q 3 Q 8 Q 13
Jeopardy Q 1 Q 6 Q 11 Q 16 Q 21 Q 2 Q 7 Q 12 Q 17 Q 22 Q 3 Q 8 Q 13

Jeopardy Q 1 Q 6 Q 11 Q 16 Q 21 Q 2 Q 7 Q 12 Q 17 Q 22 Q 3 Q 8 Q 13
0 - 0.

0 - 0.
2 pt 3 pt 4 pt 5 pt 1 pt 2 pt 3 pt 4 pt 5 pt 1 pt 2 pt 3 pt 4 pt 5 pt 1 pt 2 pt 3 pt 4 pt 5 pt 1 pt 2 pt 3 pt 4 pt 5 pt 1 pt Time Money AdditionSubtraction.

2 pt 3 pt 4 pt 5 pt 1 pt 2 pt 3 pt 4 pt 5 pt 1 pt 2 pt 3 pt 4 pt 5 pt 1 pt 2 pt 3 pt 4 pt 5 pt 1 pt 2 pt 3 pt 4 pt 5 pt 1 pt Time Money AdditionSubtraction.
DIVIDING INTEGERS 1. IF THE SIGNS ARE THE SAME THE ANSWER IS POSITIVE 2. IF THE SIGNS ARE DIFFERENT THE ANSWER IS NEGATIVE.

DIVIDING INTEGERS 1. IF THE SIGNS ARE THE SAME THE ANSWER IS POSITIVE 2. IF THE SIGNS ARE DIFFERENT THE ANSWER IS NEGATIVE.
MULTIPLYING MONOMIALS TIMES POLYNOMIALS (DISTRIBUTIVE PROPERTY)

MULTIPLYING MONOMIALS TIMES POLYNOMIALS (DISTRIBUTIVE PROPERTY)
ADDING INTEGERS 1. POS. + POS. = POS. 2. NEG. + NEG. = NEG. 3. POS. + NEG. OR NEG. + POS. SUBTRACT TAKE SIGN OF BIGGER ABSOLUTE VALUE.

ADDING INTEGERS 1. POS. + POS. = POS. 2. NEG. + NEG. = NEG. 3. POS. + NEG. OR NEG. + POS. SUBTRACT TAKE SIGN OF BIGGER ABSOLUTE VALUE.
MULTIPLICATION EQUATIONS 1. SOLVE FOR X 3. WHAT EVER YOU DO TO ONE SIDE YOU HAVE TO DO TO THE OTHER 2. DIVIDE BY THE NUMBER IN FRONT OF THE VARIABLE.

MULTIPLICATION EQUATIONS 1. SOLVE FOR X 3. WHAT EVER YOU DO TO ONE SIDE YOU HAVE TO DO TO THE OTHER 2. DIVIDE BY THE NUMBER IN FRONT OF THE VARIABLE.
SUBTRACTING INTEGERS 1. CHANGE THE SUBTRACTION SIGN TO ADDITION

SUBTRACTING INTEGERS 1. CHANGE THE SUBTRACTION SIGN TO ADDITION

Similar presentations

Ads by Google