Proceedings & Abstracts

Ji, S. (1991).  The “Table Theory”: A New Method in Theoretical Biology.  In: Molecular Theories of Cell Life and Death. (Ji, S., ed.).  Rutgers University Press, New Brunswick.  Pp. 8-13.

Ji, S. (1991).  The “Molecularization” of Machines and the “Thermal Barrier”.  In: Molecular Theories of Cell Life and Death. (Ji, S., ed.).  Rutgers University Press, New Brunswick.  Pp. 29-35

Ji, S. (1991).  The Principle of Slow and Fast Processes or the Generalized Franck-Condon Principle.  In: Molecular Theories of Cell Life and Death. (Ji, S., ed.).  Rutgers University Press, New Brunswick.  Pp. 53-56.

Ji, S. (1991).  Manifolds, Fractals, Fiber Bundles, and Gauge Fields: The Role of  Genetic Information in the Theory of the Cell Force.  In: Molecular Theories of Cell Life and Death. (Ji, S., ed.).  Rutgers University Press, New Brunswick.  Pp. 90-122.

Ji, S. (1991).  The Cell as the Atom of Biology.   In: Molecular Theories of Cell Life and Death. (Ji, S., ed.).  Rutgers University Press, New Brunswick.  Pp. 62-77.

Ji, S. (1991).  The Bhopalator (Part A): A Theoretical Model of the Cell. In: Molecular Theories of Cell Life and Death. (Ji, S., ed.).  Rutgers University Press, New Brunswick.  Pp. 77-100.

Ji, S. (1991).  The Bhopalator (Part B): A Theoretical Model of the Cell. In: Molecular Theories of Cell Life and Death. (Ji, S., ed.).  Rutgers University Press, New Brunswick.  Pp. 77-101-119.

Ji, S. (1991).  A Biological Model of the Universe: The Shillongator.  In: Molecular Theories of Cell Life and Death.  Rutgers University Press, New Brunswick.  Section 1.11, pp. 152-163, 230-237.

Ji, S. (1991).  A General Theory of ATP Synthesis and Utilization. In: Molecular Theories of Cell Life and Death. (Ji, S., ed.).  Rutgers University Press, New Brunswick.  Pp. 211-226.

Ji, S. (1991).  A Biological Model of the Universe: The Shillongator.  In: Molecular Theories of Cell Life and Death. (Ji, S., ed.).  Rutgers University Press, New Brunswick.  Pp. 152-163, 230-237.

Ji, S. (1991).  Manifolds, Fractals, Fiber Bundles, Gauge Fields: The Roles of Genetic Information in the Theory of the Cell Force. In: Molecular Theories of Cell Life and Death. (Ji, S., ed.).  Rutgers University Press, New Brunswick.  Pp. 90-122.

Ji, S. (1993). Complementarism: A New Dialogue Between Science and Religion. Proceedings of the KSEA Northeast Regional Conference, pp. 319-328.

Ji, S. (1995).  Complementarism: A Biology-Based Philosophical Framework to Integrate Western Science and Eastern Tao, in Psychotherapy East and West: Integration of Psychotherapies, Korean Academy of Psychotherapists, 178-23 Sungbuk-dong, Songbuk-ku, Seoul 136-020, Korea, pp. 517-548.

Ji, S. (1997).  Gnergons as Quanta of Semiosic Actions.  This abstract was submitted to The Third International Conference on Semiotics, Victoria College, University of Toronto, October 17-19, 1997, upon an  invitation but was never presented at the meeting.

Ji, S. (2001). Isomorphism between Cell and Human Languages: Micro- and  Macrosemiotics, in Semiotics 2000: “Sebeok’s Century”, S. Simpkins, J. Deely, (eds.), Legas, Ottawa, pp. 357-374.

Ji, S. (2003).  Towards a Unified Theory of Computing, Mind, and Signs.  In: Brainstorming Week on Membrane Computing (Cavaliere, M, Martin-Vide, C. and Paun, G., eds.). Research Group on Mathematical Linguistics, University of Rovira and Virgili, Taragona, Spain, February 5-11.

Ji, S. (2003). Computing with Numbers, Words or Molecules. Reports of the Research Group on Mathematical Linguistics (Martin-Vide, C., ed.), University of Rovira and Virgili, Tarragona, Spain.

Frisco, P., and Ji, S. (2003).  Towards a Hierarchy of Conformons-P Systems. Lecture Notes in Computer Science 2597: 302-318.

Ji, S. (2004).  Semiotics of Life: A Unified Theory of Molecular Machines, Cells, the Mind, Peircean Signs, and the Universe based on the Principle of Information-Energy Complementarity.  In: Reports, Research Group on Mathematical Iinguistics, XVII Tarragona Seminar on Formal Syntax and Semantics, Rovira i Virgili University, Tarragona, 23-27 April 2003.

Ji, S., Eom, J.-k., and Miura, R. (2004). Kinetic Model-Based Analysis of Microarray data. The 7th Microarray Gene Expression Data Society International Meeting, Toronto, September 8-10.

Ji, S. (2006). The Proteome as an Autonomous Molecular Language: “Proteinese” A Poster presented at the DIMACS Workshop on Sequences, Structure and Systems Approaches to Predict Protein Function, Rutgers University, Piscataway, May 3-5, 2006.

Ji, S. (2006). How To Avoid Misinterpreting DNA Microarray Data. DIMACS Workshop on Machine Learning Techniques in Bioinformatics, Center for Discrete Mathematics and Theoretical Computer Science, Rutgers University, Piscataway, N.J. 08855, July 11-12.

Ji, S. (2008).  Modeling the single-molecule enzyme kinetics of cholesterol oxidase  based on Planck’s radiation formula ad the principle of enthalpy-entropy compensation, in Short Talk Abstracts,  The 100th Statistical Mechanics Conference, Rutgers University, Piscataway, N.J. 08854.

Cheng, L., Yao, D. and Ji, S. (2012).  Differential Poisson distributions of beneficial and harmful RNA dissipative structures (dissipatons) in breast cancer patients.  In Short Talk Abstracts, The 108^th Statistical Mechanics Conference, Rutgers University, Piscataway.

Ji, S., Chaovalitwongse, W. A., Fefferman, N., Yoo, W. and Perez-Ortin, J. E. (2009).  Mechanism-based Clustering of Genome-wide RNA Levels: Roles of Transcription and Transcript-Degradation Rates.  In: Clustering Challenges in Biological Networks (Butenko, S., Chaovalitwongse, W. A. and Pardalos, P. M., eds.), World Scientific.  Pp. 237-255.

Ji, S. (2016). WAVE-PARTICLE DUALITY IN PHYSICS AND BIOMEDICAL SCIENCES.  Symmetry: Science and Culture 27 (2): 99-127 (2016).

Ji, S. (2015). Planckian distributions in molecular machines, living cells, and brains: The wave-particle duality in biomedical sciences.  In: Proceedings of the International Conference on Biology and Biomedical Engineering, Vienna, March 15-17, 2015. Pp. 115-137.

Ji, S. (2015). PLANCKIAN INFORMATION (IP): A NEW MEASURE OF ORDER IN ATOMS, ENZYMES, CELLS, BRAINS, HUMAN SOCIETIES, AND THE COSMOS.  In: Unified Field Mechanics: Natural Science beyond the Veil of Spacetime (Amoroso, R., Rowlands, P., and Kauffman, L. eds.), World Scientific, New Jersey, 2015, pp. 579-589)