Molecular Computing and Bioinformatics

Information processing is essential for any lifeform to maintain its organisation despite continuous entropic disturbance. Macromolecules provide the ubiquitous underlying substrate on which nature implements information processing and have also come into focus for technical applications. There are two distinct approaches to the use of molecules for computing. Molecules can be employed to mimic the logic switches of conventional computers or they can be used in a way that exploits the complex functionality offered by a molecular computing substrate. Prerequisite to the latter is a mapping of input-output transform provided by the substrate. This paper reviews microfluidic technology as a versatile means to achieve this, show how it can be used, and provide proven recipes for its application.

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Analysis of a Digital Clock for Molecular Computing

2007 American Control Conference ◽

10.1109/acc.2007.4282583 ◽

2007 ◽

Cited By ~ 1

Author(s):

Johan Ugander ◽

Mary J. Dunlop ◽

Richard M. Murray

Keyword(s):

Molecular Computing ◽

Digital Clock

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S02I6 Molecular Communication Using Vesicles and Molecular Motors(Molecular Computing and Molecular Communication: New Computing and Communication Systems Using Biological Functions)

Seibutsu Butsuri ◽

10.2142/biophys.47.s3_3 ◽

2007 ◽

Vol 47 (supplement) ◽

pp. S3

Author(s):

Satoshi Hiyama ◽

Yuki Moritani ◽

Tatsuya Suda

Keyword(s):

Molecular Motors ◽

Communication Systems ◽

Molecular Computing ◽

Biological Functions ◽

Molecular Communication

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State Transition Dynamics

Molecular Computational Models - Advances in Web Services Research ◽

10.4018/978-1-59140-333-3.ch002 ◽

2011 ◽

pp. 32-55 ◽

Cited By ~ 8

Author(s):

Vincenzo Manca ◽

Giuditta Franco ◽

Giuseppe Scollo

Keyword(s):

Dynamical Systems ◽

State Transition ◽

Molecular Computing ◽

Discrete Models ◽

Classical Dynamics ◽

Transition Systems ◽

Transition Dynamics ◽

Models Of Computation ◽

Simple Set ◽

State Transition Systems

Classical dynamics concepts are analysed in the basic mathematical setting of state transition systems where time and space are both completely discrete and no structure is assumed on the state’s space. Interesting relationships between attractors and recurrence are identified and some features of chaos are expressed in simple, set theoretic terms. String dynamics is proposed as a unifying concept for dynamical systems arising from discrete models of computation, together with illustrative examples. The relevance of state transition systems and string dynamics is discussed from the perspective of molecular computing.

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Linearizer and Doubler : Two Mappings to Unify Molecular Computing Models Based on DNA Complementarity

DNA Computing - Lecture Notes in Computer Science ◽

10.1007/11753681_18 ◽

2006 ◽

pp. 224-235 ◽

Cited By ~ 1

Author(s):

Kaoru Onodera ◽

Takashi Yokomori

Keyword(s):

Molecular Computing ◽

Computing Models

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Bio-Molecular Computing of Finite-State Machine

Proceedings of the Third International Conference on Bio-Inspired Models of Network Information and Computing Systems (Bionetics 2008) ◽

10.4108/icst.bionetics2008.4744 ◽

2008 ◽

Cited By ~ 1

Author(s):

Yasubumi Sakakibara

Keyword(s):

Finite State Machine ◽

State Machine ◽

Molecular Computing ◽

Finite State

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Molecular Computing and Bioinformatics

Molecules ◽

10.3390/molecules24132358 ◽

2019 ◽

Vol 24 (13) ◽

pp. 2358

Author(s):

Xin Liang ◽

Wen Zhu ◽

Zhibin Lv ◽

Quan Zou

Keyword(s):

Organic Chemistry ◽

Molecular Biology ◽

Smart Materials ◽

Close Relationships ◽

Molecular Computing ◽

The Core ◽

Computer Scientists ◽

Novel Algorithms ◽

Silicon Based ◽

Molecular Computers

Molecular computing and bioinformatics are two important interdisciplinary sciences that study molecules and computers. Molecular computing is a branch of computing that uses DNA, biochemistry, and molecular biology hardware, instead of traditional silicon-based computer technologies. Research and development in this area concerns theory, experiments, and applications of molecular computing. The core advantage of molecular computing is its potential to pack vastly more circuitry onto a microchip than silicon will ever be capable of—and to do it cheaply. Molecules are only a few nanometers in size, making it possible to manufacture chips that contain billions—even trillions—of switches and components. To develop molecular computers, computer scientists must draw on expertise in subjects not usually associated with their field, including organic chemistry, molecular biology, bioengineering, and smart materials. Bioinformatics works on the contrary; bioinformatics researchers develop novel algorithms or software tools for computing or predicting the molecular structure or function. Molecular computing and bioinformatics pay attention to the same object, and have close relationships, but work toward different orientations.

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