Stochastic Analysis of the Motion of DNA Nanomechanical Bipeds

Ben-Ari, Iddo; Boushaba, Khalid; Matzavinos, Anastasios; Roitershtein, Alexander

doi:10.1007/s11538-010-9600-x

Cited by 8 publications

(27 citation statements)

References 23 publications

(21 reference statements)

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“…Analytical results regarding the asymptotic behaviors (limit theorems, transience, recurrence, and rate of escape) of spiders have been derived in Refs. [25,26]. In Refs.…”

Section: Introductionmentioning

confidence: 99%

First-passage properties of molecular spiders

2013

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Molecular spiders are synthetic catalytic DNA-based nanoscale walkers. We study the mean first passage time for abstract models of spiders moving on a finite two-dimensional lattice with various boundary conditions, and compare it with the mean first passage time of spiders moving on a onedimensional track. We evaluate by how much the slowdown on newly visited sites, owing to catalysis, can improve the mean first passage time of spiders and show that in one dimension, when both ends of the track are an absorbing boundary, the performance gain is lower than in two dimensions, when the absorbing boundary is a circle; this persists even when the absorbing boundary is a single site.

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“…Analytical results regarding the asymptotic behaviors (limit theorems, transience, recurrence, and rate of escape) of spiders have been derived in Refs. [25,26]. In Refs.…”

Section: Introductionmentioning

confidence: 99%

First-passage properties of molecular spiders

2013

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“…An interesting new feature noticed in [16] is the emergence of a super-diffusive growth of the mean-square displacement, x 2 (t) ∼ t α with 1 < α < 2, which holds on a surprisingly long time span; eventually, the super-diffusive growth crosses over to the diffusive growth. Several rigorous results concerning the asymptotic behaviors (limit theorems, transience, recurrence, and rate of escape) of molecular spiders have been established in [18,19]. In Refs.…”

Section: Introductionmentioning

confidence: 99%

Molecular spiders on a plane

Antal

Krapivsky

2012

Phys. Rev. E

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Synthetic bio-molecular spiders with "legs" made of single-stranded segments of DNA can move on a surface covered by single-stranded segments of DNA called substrates when the substrate DNA is complementary to the leg DNA. If the motion of a spider does not affect the substrates, the spider behaves asymptotically as a random walk. We study the diffusion coefficient and the number of visited sites for spiders moving on the square lattice with a substrate in each lattice site. The spider's legs hop to nearest-neighbor sites with the constraint that the distance between any two legs cannot exceed a maximal span. We establish analytic results for bipedal spiders, and investigate multileg spiders numerically. In experimental realizations legs usually convert substrates into products (visited sites). The binding of legs to products is weaker, so the hopping rate from the substrates is smaller. This makes the problem non-Markovian and we investigate it numerically. We demonstrate the emergence of a counter-intuitive behavior -the more spiders are slowed down on unvisited sites, the more motile they become.

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“…The underlying random walk in [9] is a simple random walk on the integer lattice. The one-dimensional biped model of [9] was generalized by Ben-Ari et al in [12] to include asymmetric transition rates. For a general discussion on asymmetric spiders see, for instance, [69] and references therein.…”

Section: Spider Random Walk: General Mathematical Frameworkmentioning

confidence: 99%

“…The underlying random walk is a continuous-time process, which in general may be controlled, self-interacting or in random media, and thus it does not have to be Markovian. In [7] and [12] the underlying random walk is a usual nearest-neighbor random walk on the integer lattice Z, in [9] it is a 1-excited random walk (ERW) on Z introduced in [14], and in [37] it is a random walk in random environment (RWRE) on Z (see for instance [97] for a survey on RWRE). In [36] the authors considered a general graph G and a spider with leg relocation dynamics evolving according to the law of a nearest-neighbor symmetric random walk on G. Most of the work in [36] focuses on recurrence and transience criteria and on comparing the spider random walk to the simple nearest-neighbor random walk on the same tree.…”

Section: Spider Random Walk: General Mathematical Frameworkmentioning

confidence: 99%

“…In [12] the authors considered an asymmetric bipedal spider, sometimes referred to as a molecular biped in the following, with in general different transition mechanisms (underlying random walks) associated with each leg. The main results in [12] are a strong law of large numbers and a functional central limit theorem for the location of the molecular biped with explicit expressions for the asymptotic velocity and limiting variance.…”

Section: Spider Random Walk: General Mathematical Frameworkmentioning

confidence: 99%

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Spider walk in a random environment

Takhistova¹

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We analyze a random process in a random media modeling the motion of DNA nanomechanical walking devices. We consider a molecular spider restricted to a well-defined one-dimensional track and study its asymptotic behavior in an i. i. d. random environment. The spider walk is a continuous time motion of a finite ensemble of particles on the integer lattice with the jump rates determined by the environment. The particles mutual location must belong to a given finite set of configurations L, and the motion can be alternatively described as a random walk on the ladder graph Z × L in a stationary and ergodic environment. Our main result is an annealed central limit theorem for this process. We believe that the conditions of the theorem are close to necessary.

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Stochastic Analysis of the Motion of DNA Nanomechanical Bipeds

Cited by 8 publications

References 23 publications

First-passage properties of molecular spiders

First-passage properties of molecular spiders

Molecular spiders on a plane

Spider walk in a random environment

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