Computational regulatory model for detoxification of ammonia from urea cycle in liver

Ali, Rashith Muhammad Mubarak; Gurusamy, Poornima Devi; Ramachandran, Selvakumar

doi:10.3906/biy-1401-50

Cited by 4 publications

(1 citation statement)

References 17 publications

(24 reference statements)

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“…Such a machine assists in scrutinizing the completion of urea cycle for degradation of ammonia into urea which is then excreted. This computational model also suggests the regulation of the enzymatic activity which can serve as a therapeutic application focusing on molecular targeted treatment for urea cycle disorders (UCD), brain damage and other related deficiencies due to ammonia toxicity (Ali et al 2014). …”

Section: Automatamentioning

confidence: 99%

Computational model for monitoring cholesterol metabolism

2014

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A non-deterministic finite automaton is designed to observe the cholesterol metabolism with the states of acceptance and rejection. The acceptance state of the automaton depicts the normal level of metabolism and production of good cholesterol as an end product. The rejection state of this machine shows the inhibition of enzymatic activity in cholesterol synthesis and removal of free fatty acids. The deficiency in human cholesterol metabolism pathway results in abnormal accumulation of cholesterol in plasma, arterial tissues leading to diseases such as hypercholesterolemia, atherosclerosis respectively and formation of gallstones. The designed machine can be used to monitor the cholesterol metabolism at molecular level through regulation of enzymes involved in the biosynthesis and metabolism of cholesterol for the treatment of diseases incident due to the respective metabolic disorder. In addition, an algorithm for this machine has been developed to compare the programmed string with the given string. This study demonstrates the construction of a machine that is used for the development of molecular targeted therapy for the disorders in cholesterol metabolism.

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Section: Automatamentioning

confidence: 99%

Computational model for monitoring cholesterol metabolism

2014

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Theory of tailor automata

Waldmajer

Bonikowski

Sakowski

2019

Theoretical Computer Science

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A detailed experimental study of a DNA computer with two endonucleases

Sakowski

Krasiński

Sarnik

et al. 2017

Zeitschrift Für Naturforschung C

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Great advances in biotechnology have allowed the construction of a computer from DNA. One of the proposed solutions is a biomolecular finite automaton, a simple two-state DNA computer without memory, which was presented by Ehud Shapiro's group at the Weizmann Institute of Science. The main problem with this computer, in which biomolecules carry out logical operations, is its complexity - increasing the number of states of biomolecular automata. In this study, we constructed (in laboratory conditions) a six-state DNA computer that uses two endonucleases (e.g. AcuI and BbvI) and a ligase. We have presented a detailed experimental verification of its feasibility. We described the effect of the number of states, the length of input data, and the nondeterminism on the computing process. We also tested different automata (with three, four, and six states) running on various accepted input words of different lengths such as ab, aab, aaab, ababa, and of an unaccepted word ba. Moreover, this article presents the reaction optimization and the methods of eliminating certain biochemical problems occurring in the implementation of a biomolecular DNA automaton based on two endonucleases.

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Computational regulatory model for detoxification of ammonia from urea cycle in liver

Cited by 4 publications

References 17 publications

Computational model for monitoring cholesterol metabolism

Computational model for monitoring cholesterol metabolism

Theory of tailor automata

A detailed experimental study of a DNA computer with two endonucleases

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