Ushiki's theorem: Difference between revisions

From formulasearchengine
Jump to navigation Jump to search
en>Brad7777
 
 
Line 1: Line 1:
The sharpening system for straight blades is a two half system consisting of carbide sharpening rods for very uninteresting blades and ceramic rods for honing/tremendous tuning blades. Each sets of sharpening rods are reversible and replaceable however there's not an adjustment for the angle of the rods and given the compact design there is not enough room to adjust the knife blade to the rod groove. For serrated edges the pocket sharpener has a fold out, tapered diamond file. The only other function for this straightforward, compact, pocket sharpener is an built-in lanyard hole which allows the consumer to connect it to gear or a belt loop.<br><br>Take into account, lighter doesn’t at all times mean higher. Aluminium saves weight, however metal is stronger. Titanium is very strong and lightweight, however costs a bit extra. Evaluate weights of various models and then research the development or evaluations to verify it might [http://www.Thebestpocketknifereviews.com/ Best Pocket Knife 2014] stand as much as some day by day abuse. Talking concerning the variety of different locking strategies out there is a lot like trying to argue about which American muscle car is the most effective. They’re all great. Check them out within the store and feel which one you favor. The essential types are<br><br>Reviewers have rated this knife four.5 stars, stating that it is the “perfect EDC” as well as “best EDC knife accessible for the value.” Given its tremendous low value of $fifty eight, KnifeUp agrees and recommends this knife as the highest knife for anyone who wants an throughout good knife for everyday use. Conclusion So, you’re here searching for the most effective pocket knife! Fortuitously, you have come to the suitable place. In this article, I will speak you thru the process of discovering the perfect knife to suit your needs. As well as, I'll make a few recommendations for specific knives which may meet your needs.<br><br>Frankly speaking, there is no such thing as a serious fault and nothing to gripe about with regards to the knife itself. It's every part you expect for Ka-Bar and extra primarily based on consumer critiques. But what’s the take care of the nylon sheath? Granted, it’s free and easy to replace but it actually seems hideous. Shopper Evaluations General, the creator gives the Ka-Bar a [http://Healthcare-Innovations.Med.Nyu.edu/sessions/top-rated-pocket-knives-1 ranking] of four.5 out of 5. It could have been an ideal rating. Nevertheless, the writer really has one in all these knives and he gets chided by pals that his genuine Ka-Bar is imitation as a result of it’s stamped “made in Taiwan.” That warrants the5 deduction within the rating.<br><br>Once a blade is formed and hardened, the leading edge receives its last grind. The procedures, facets and angles used to complete an edge additional affect the preliminary sharpness and edge-holding potential of the blade. Like metal hardness, there is no single good edge end. Too narrow an angle and the blade's leading edge is simply too skinny to resist deflection and dulling, while too blunt an angle on that leading edge doesn’t feel practically as sharp in actual utilization. Like questions of material and hardening, be happy to research the totally different characteristics of the hole grind, the edge angle and single vs. double bevel.<br><br>By fastidiously weighing all of those categories, consumers can be certain that they discover the perfect knife for their wants. Knives might be bought in all totally different shapes and sizes, from jack knives and pen knives to multipurpose Swiss Army type knives. After studying in regards to the totally different forms of knives, visitors can find out about particular merchandise that meet their needs. Those who need to study extra about a particular type or model of knife can read by means of blog posts on the website. Blog posts embody articles about the very best costly pocket knives, one of the best ceramic pocket knives, and even one of the best pink pocket knives.<br><br>Shane Sibert is a person behind this nice trying folding knife. He is making knives since 1994, on his web site he claims that making high quality knives is his full time enterprise since 2004. Shane made ‘Benchmade Adamas Sibert 275 BKSN Knife ‘ to honour the dedication exhibited by American soldier’s in direction of their nation. Though it is made in honour of soldier’s; don’t misunderstand this knife as a military knife and it's never been classified as a military knife. In Reality although it's a non-military knife it does stand out for its characteristics and actually helpful in battlefield as well as for regular use in residence.<br><br>Due to the reputation of the fastened blade Ka-Bar and the clamor for a folding variation, the folding Ka-Bar Mule was designed. It’s nearly as robust because the fixed blade version and appears simply as menacing. The slight lack of [https://bergelmir.iki.his.se/trac/deeds/ticket/12370 durability] just isn't really an issue here. It's a folder for one thing, and second, the mounted blade Ka-Bar is tougher than a nail (not just as robust as one). This Ka-Bar Mule overview will speak about the Ka-Bar firm, the features and advantages of this knife, in addition to what reviewers have stated. What is Ka-Bar?<br><br>When looking for the perfect pocket knife, you will need to realize that the right knife is not the same for every particular person. The perfect knife for me won't be [http://Server0.net/index.php?title=Best_Pocket_Knife_Ever_Made perfect] for you, because the way I take advantage of my knife is perhaps [http://www.knifecenter.com/knifecenter/index/foldersm.html tops knives] different than the way you employ yours. Accordingly, to identify your needs in a knife, we should first identify your supposed use. The Back Pocket is a slipjoint knife with 3-1/four″ clip point blade. Like other slipjoint knives, the Case Back Pocket blade does not lock open. It opens by way of a nail nick and stops at a single mid-approach detent earlier than snapping into place.
The '''system size expansion''', also known as '''van Kampen's expansion''' or the '''Ω-expansion''', is a technique pioneered by van Kampen<ref name = "vankampen">van Kampen, N. G. (2007) "Stochastic Processes in Physics and Chemistry", North-Holland Personal Library</ref> used in the analysis of [[stochastic processes]]. Specifically, it allows one to find an approximation to the solution of a [[master equation]] with nonlinear transition rates. This approximation is often formulated in the '''linear noise approximation''', in which the master equation is represented by a [[Fokker–Planck equation]] with linear coefficients determined by the [[Markov process|transition rates]] and [[stochiometry]] of the system.
 
Less formally, it is normally straightforward to write down a mathematical description of a system where processes happen randomly (for example, radioactive atoms randomly [[Radioactive decay|decay]] in a physical system, or genes are [[cellular noise|randomly expressed]] in a biological system). However, these mathematical descriptions are often complicated and difficult to solve for interesting properties of the system (for example, the [[Mean (statistics)|mean]] and [[variance]] of the number of atoms or genes as a function of time). The system size expansion allows us to approximate a complicated mathematical description by a simpler one that is guaranteed to provide (approximate) results for these properties.
 
== Preliminaries ==
 
Systems that admit a treatment with the system size expansion may be described by a [[probability distribution]] <math>P(X, t)</math>, giving the probability of observing the system in state <math>X</math> at time <math>t</math>. <math>X</math> may be, for example, a [[Tuple|vector]] with elements corresponding to the number of molecules of different chemical species in a system. In a system of size <math>\Omega</math> (intuitively interpreted as the volume), we will adopt the following nomenclature: <math>\mathbf{X}</math> is a vector of macroscopic copy numbers, <math>\mathbf{x} = \mathbf{X}/\Omega</math> is a vector of concentrations, and <math>\mathbf{\phi}</math> is a vector of deterministic concentrations, as they would appear according to the rate equation in an infinite system. <math>\mathbf{x}</math> and <math>\mathbf{X}</math> are thus quantities subject to stochastic effects.
 
A [[master equation]] describes the time evolution of this probability.<ref name = "vankampen" /> Henceforth, a system of chemical reactions<ref name = "elf">Elf, J. and Ehrenberg, M. (2003) "Fast Evaluation of Fluctuations in Biochemical Networks With the Linear Noise Approximation", ''Genome Research'', 13:2475–2484.</ref> will be discussed to provide a concrete example, although the nomenclature of "species" and "reactions" is generalisable. A system involving <math>N</math> species and <math>R</math> reactions can be described with the master equation:
 
:<math> \frac{d P(\mathbf{X}, t)}{dt} = \Omega \sum_{j = 1}^R \left( \prod_{i = 1}^{N} \mathbb{E}^{-S_{ij}} - 1 \right) f_j (\mathbf{x}, \Omega) P (\mathbf{X}, t). </math>
 
Here, <math>\Omega</math> is the system size, <math>\mathbb{E}</math> is an [[Operator (mathematics)|operator]] which will be addressed later, <math>S_{ij}</math> is the stochiometric matrix for the system (in which element <math>S_{ij}</math> gives the [[Stoichiometry#Stoichiometry_matrix|stoichiometric coefficient]] for species <math>i</math> in reaction <math>j</math>), and <math>f_j</math> is the rate of reaction <math>j</math> given a state <math>\mathbf{x}</math> and system size <math>\Omega</math>.
 
<math>\mathbb{E}^{-S_{ij}}</math> is a step operator,<ref name = "vankampen" /> removing <math>S_{ij}</math> from the <math>i</math>th element of its argument. For example, <math>\mathbb{E}^{-S_{23}} f(x_1, x_2, x_3) = f(x_1, x_2 - S_{23}, x_3)</math>. This formalism will be useful later.
 
The above equation can be interpreted as follows. The initial sum on the RHS is over all reactions. For each reaction <math>j</math>, the brackets immediately following the sum give two terms. The term with the simple coefficient −1 gives the probability flux away from a given state <math>\mathbf{X}</math> due to reaction <math>j</math> changing the state. The term preceded by the product of step operators gives the probability flux due to reaction <math>j</math> changing a different state <math>\mathbf{X'}</math> into state <math>\mathbf{X}</math>. The product of step operators constructs this state <math>\mathbf{X'}</math>.
 
=== Example ===
 
For example, consider the (linear) chemical system involving two chemical species <math>X_1</math> and <math>X_2</math> and the reaction <math>X_1 \rightarrow X_2</math>. In this system, <math>N = 2</math> (species), <math>R = 1</math> (reactions). A state of the system is a vector <math>\mathbf{X} = \{ n_1, n_2 \}</math>, where <math>n_1, n_2</math> are the number of molecules of <math>X_1</math> and <math>X_2</math> respectively. Let <math>f_1(\mathbf{x}, \Omega) = \frac{n_1}{\Omega} = x_1</math>, so that the rate of reaction 1 (the only reaction) depends on the concentration of <math>X_1</math>. The stochiometry matrix is <math>(-1, 1)^T</math>.
 
Then the master equation reads:
 
:<math>\begin{align} \frac{d P(\mathbf{X}, t)}{dt} & = \Omega \left( \mathbb{E}^{-S_{11}} \mathbb{E}^{-S_{21}} - 1 \right) f_1 \left( \frac{\mathbf{X}}{\Omega} \right) P(\mathbf{X}, t) \\
& = \Omega \left( f_1 \left( \frac{\mathbf{X} + \mathbf{\Delta X}}{\Omega} \right) P \left( \mathbf{X} + \mathbf{\Delta X}, t \right)  - f_1 \left( \frac{\mathbf{X}}{\Omega} \right) P \left( \mathbf{X}, t \right) \right),\end{align}</math>
 
where <math>\mathbf{\Delta X} = \{1, -1\}</math> is the shift caused by the action of the product of step operators, required to change state <math>\mathbf{X}</math> to a precursor state <math>\mathbf{X}'</math>.
 
== Linear Noise Approximation ==
 
If the master equation possesses [[nonlinear system|nonlinear]] transition rates, it may be impossible to solve it analytically. The system size expansion utilises the [[ansatz]] that the [[variance]] of the steady-state probability distribution of constituent numbers in a population scales like the system size. This ansatz is used to expand the master equation in terms of a small parameter given by the inverse system size.
 
Specifically, let us write the <math>X_i</math>, the copy number of component <math>i</math>, as a sum of its "deterministic" value (a scaled-up concentration) and a [[random variable]] <math>\xi</math>, scaled by <math>\Omega^{1/2}</math>:
 
:<math> X_i = \Omega \phi_i + \Omega^{1/2} \xi_i. </math>
 
The probability distribution of <math>\mathbf{X}</math> can then be rewritten in the vector of random variables <math>\xi</math>:
 
:<math> P(\mathbf{X}, t) = P(\Omega \mathbf{\phi} + \Omega^{1/2} \mathbf{\xi}) = \Pi (\mathbf{\xi}, t). </math>
 
Let us consider how to write reaction rates <math>f</math> and the step operator <math>\mathbb{E}</math> in terms of this new random variable. [[Taylor expansion]] of the transition rates gives:
 
:<math> f_j (\mathbf{x}) = f_j (\mathbf{\phi} + \Omega^{-1/2} \mathbf{\xi}) = f_j( \mathbf{\phi} ) + \Omega^{-1/2} \sum_{i = 1}^N \frac{\partial f'_j(\mathbf{\phi})}{\partial \phi_i} \xi_i + O(\Omega^{-1}). </math>
 
The step operator has the effect <math>\mathbb{E} f(n) \rightarrow f(n+1)</math> and hence <math>\mathbb{E} f(\xi) \rightarrow f(\xi + \Omega^{-1/2})</math>:
 
:<math> \prod_{i = 1}^{N}\mathbb{E}^{-S_{ij}} \simeq 1 - \Omega^{-1/2} \sum_i S_{ij} \frac{\partial}{\partial \xi_i} + \frac{\Omega^{-1}}{2} \sum_i \sum_k S_{ij} S_{kj} \frac{\partial^2}{\partial \xi_i \, \partial \xi_k} + O(\Omega^{-3/2}). </math>
 
We are now in a position to recast the master equation.
 
:<math> \begin{align} & {} \quad \frac{\partial \Pi(\mathbf{\xi}, t)}{\partial t} - \Omega^{1/2} \sum_{i = 1}^N \frac{\partial \phi_i}{\partial t} \frac{\partial \Pi(\mathbf{\xi}, t)}{\partial \xi_i} \\
& = \Omega \sum_{j = 1}^R \left( -\Omega^{-1/2} \sum_i S_{ij} \frac{\partial}{\partial \xi_i} + \frac{\Omega^{-1}}{2} \sum_i \sum_k S_{ij} S_{kj} \frac{\partial^2}{\partial \xi_i \, \partial \xi_k} + O(\Omega^{-3/2}) \right) \\
& {} \qquad \times \left( f_j(\mathbf{\phi}) + \Omega^{-1/2} \sum_i \frac{\partial f'_j(\mathbf{\phi})}{\partial \phi_i} \xi_i + O(\Omega^{-1}) \right) \Pi(\mathbf{\xi}, t). \end{align}</math>
 
This rather frightening expression makes a bit more sense when we gather terms in different powers of <math>\Omega</math>. First, terms of order <math>\Omega^{1/2}</math> give
 
:<math>\sum_{i = 1}^N \frac{\partial \phi_i}{\partial t} \frac{\partial \Pi(\mathbf{\xi}, t)}{\partial \xi_i} = \sum_{i = 1}^N \sum_{j = 1}^R S_{ij} f'_j (\mathbf{\phi}) \frac{\partial \Pi(\mathbf{\xi}, t)}{\partial \xi_j}. </math>
 
These terms cancel, due to the [[Rate equation|macroscopic reaction equation]]
 
:<math> \frac{\partial \phi_i}{\partial t} = \sum_{j = 1}^R S_{ij} f'_j (\mathbf{\phi}). </math>
 
The terms of order <math>\Omega^0</math> are more interesting:
 
:<math> \frac{\partial \Pi (\mathbf{\xi}, t)}{\partial t} = \sum_j \left( \sum_{ik} -S_{ij} \frac{\partial f'_j}{\partial \phi_k} \frac{\partial (\xi_k \Pi (\mathbf{\xi}, t) )}{\partial \xi_i} + \frac{1}{2} f'_j \sum_{ik} S_{ij} S_{kj} \frac{\partial^2 \Pi (\mathbf{\xi}, t)}{\partial \xi_i \, \partial \xi_k} \right), </math>
 
which can be written as
 
:<math> \frac{\partial \Pi (\mathbf{\xi}, t)}{\partial t} = \sum_{ik} A_{ik} \frac{\partial (\xi_k \Pi)}{\partial \xi_i} + \frac{1}{2} \sum_{ik} [\mathbf{BB}^T]_{ik} \frac{\partial^2 \Pi}{\partial \xi_i \, \partial \xi_k}, </math>
 
where
 
:<math> A_{ik} = \sum_{j = 1}^R S_{ij} \frac{\partial f'_j}{\partial \phi_k} = \frac{\partial (\mathbf{S}_i \cdot \mathbf{f})}{\partial \phi_k}, </math>
 
and
 
:<math> [ \mathbf{BB}^T ]_{ik} = \sum_{j = 1}^R S_{ij}S_{kj} f'_j (\mathbf{\phi}) = [ \mathbf{S} \, \mbox{diag}(f(\mathbf{\phi})) \, \mathbf{S}^T ]_{ik}. </math>
 
The time evolution of <math>\Pi</math> is then governed by the linear [[Fokker–Planck equation]] with coefficient matrices <math>\mathbf{A}</math> and <math>\mathbf{BB}^T</math> (in the large-<math>\Omega</math> limit, terms of <math>O(\Omega^{-1/2})</math> may be neglected, termed the '''linear noise approximation'''). With knowledge of the reaction rates <math>\mathbf{f}</math> and stochiometry <math>S</math>, the moments of <math>\Pi</math> can then be calculated.
 
== Applications to modeling stochastic reaction kinetics inside cells and higher order corrections ==
 
The linear noise approximation has become a popular technique for estimating the size of [[Cellular noise|intrinsic noise]] in terms of [[Coefficient of variation|coefficients of variation]] and [[Fano factor]]s for molecular species in intracellular pathways. The second moment obtained from the linear noise approximation (on which the noise measures are based) are exact only if the pathway is composed of first-order reactions. However bimolecular reactions such as [[Enzyme kinetics|enzyme-substrate]], [[Protein-protein interaction|protein-protein]] and [[Protein-DNA interaction|protein-DNA]] interactions are ubiquitous elements of all known pathways; for such cases, the linear noise approximation can give estimates which are accurate in the limit of large reaction volumes. Since this limit is taken at constant concentrations, it follows that the linear noise approximation gives accurate results in the limit of large molecule numbers and becomes less reliable for pathways characterized by many species with low copy numbers of molecules.
 
A number of studies have elucidated cases of the insufficiency of the linear noise approximation in biological contexts by comparison of its predictions with those of stochastic simulations.<ref name="hayot">Hayot, F. and Jayaprakash, C. (2004), "The linear noise approximation for molecular fluctuations within cells", ''Physical Biology'', 1:205</ref><ref name="ferm">Ferm, L. Lötstedt, P. and Hellander, A. (2008), "A Hierarchy of Approximations of the Master Equation Scaled by a Size Parameter", ''Journal of Scientific Computing'', 34:127</ref> This has led to the investigation of higher order terms of the system size expansion that go beyond the linear approximation. These terms have been used to obtain more accurate moment estimates for the [[Arithmetic mean|mean]] concentrations and for the [[variance]]s of the concentration fluctuations in intracellular pathways. In particular, the leading order corrections to the linear noise approximation yield corrections of the conventional [[rate equation]]s.<ref name = "grima2010">Grima, R. (2010) "An effective rate equation approach to reaction kinetics in small volumes: Theory and application to biochemical reactions in nonequilibrium steady-state conditions", ''The Journal of Chemical Physics'', 132:035101</ref> Terms of higher order have also been used to obtain corrections to the [[variance]]s and [[covariance]]s estimates of the linear noise approximation.<ref name="grima2011">Grima, R. and Thomas, P. and Straube, A.V. (2011), "How accurate are the nonlinear chemical Fokker-Planck and chemical Langevin equations?", ''The Journal of Chemical Physics'', 135:084103</ref><ref name="grima2012">Grima, R. (2012), "A study of the accuracy of moment-closure approximations for stochastic chemical kinetics", ''The Journal of Chemical Physics'', 136: 154105</ref> The linear noise approximation and corrections to it can be computed using the open source software [[intrinsic Noise Analyzer]]. The corrections have been shown to be particularly considerable for [[Allosteric regulation|allosteric]] and non-allosteric enzyme-mediated reactions in [[Cellular compartment|intracellular compartments]].
 
== References ==
<!--- See http://en.wikipedia.org/wiki/Wikipedia:Footnotes on how to create references using <ref></ref> tags which will then appear here automatically -->
{{Reflist}}
 
{{DEFAULTSORT:System Size Expansion}}
[[Category:Articles created via the Article Wizard]]
[[Category:Stochastic processes]]
[[Category:Applied mathematics]]
[[Category:Chemical kinetics]]
[[Category:Stoichiometry]]
[[Category:Concepts in physics]]

Latest revision as of 18:21, 31 May 2013

The system size expansion, also known as van Kampen's expansion or the Ω-expansion, is a technique pioneered by van Kampen[1] used in the analysis of stochastic processes. Specifically, it allows one to find an approximation to the solution of a master equation with nonlinear transition rates. This approximation is often formulated in the linear noise approximation, in which the master equation is represented by a Fokker–Planck equation with linear coefficients determined by the transition rates and stochiometry of the system.

Less formally, it is normally straightforward to write down a mathematical description of a system where processes happen randomly (for example, radioactive atoms randomly decay in a physical system, or genes are randomly expressed in a biological system). However, these mathematical descriptions are often complicated and difficult to solve for interesting properties of the system (for example, the mean and variance of the number of atoms or genes as a function of time). The system size expansion allows us to approximate a complicated mathematical description by a simpler one that is guaranteed to provide (approximate) results for these properties.

Preliminaries

Systems that admit a treatment with the system size expansion may be described by a probability distribution P(X,t), giving the probability of observing the system in state X at time t. X may be, for example, a vector with elements corresponding to the number of molecules of different chemical species in a system. In a system of size Ω (intuitively interpreted as the volume), we will adopt the following nomenclature: X is a vector of macroscopic copy numbers, x=X/Ω is a vector of concentrations, and ϕ is a vector of deterministic concentrations, as they would appear according to the rate equation in an infinite system. x and X are thus quantities subject to stochastic effects.

A master equation describes the time evolution of this probability.[1] Henceforth, a system of chemical reactions[2] will be discussed to provide a concrete example, although the nomenclature of "species" and "reactions" is generalisable. A system involving N species and R reactions can be described with the master equation:

dP(X,t)dt=Ωj=1R(i=1N𝔼Sij1)fj(x,Ω)P(X,t).

Here, Ω is the system size, 𝔼 is an operator which will be addressed later, Sij is the stochiometric matrix for the system (in which element Sij gives the stoichiometric coefficient for species i in reaction j), and fj is the rate of reaction j given a state x and system size Ω.

𝔼Sij is a step operator,[1] removing Sij from the ith element of its argument. For example, 𝔼S23f(x1,x2,x3)=f(x1,x2S23,x3). This formalism will be useful later.

The above equation can be interpreted as follows. The initial sum on the RHS is over all reactions. For each reaction j, the brackets immediately following the sum give two terms. The term with the simple coefficient −1 gives the probability flux away from a given state X due to reaction j changing the state. The term preceded by the product of step operators gives the probability flux due to reaction j changing a different state X into state X. The product of step operators constructs this state X.

Example

For example, consider the (linear) chemical system involving two chemical species X1 and X2 and the reaction X1X2. In this system, N=2 (species), R=1 (reactions). A state of the system is a vector X={n1,n2}, where n1,n2 are the number of molecules of X1 and X2 respectively. Let f1(x,Ω)=n1Ω=x1, so that the rate of reaction 1 (the only reaction) depends on the concentration of X1. The stochiometry matrix is (1,1)T.

Then the master equation reads:

dP(X,t)dt=Ω(𝔼S11𝔼S211)f1(XΩ)P(X,t)=Ω(f1(X+ΔXΩ)P(X+ΔX,t)f1(XΩ)P(X,t)),

where ΔX={1,1} is the shift caused by the action of the product of step operators, required to change state X to a precursor state X.

Linear Noise Approximation

If the master equation possesses nonlinear transition rates, it may be impossible to solve it analytically. The system size expansion utilises the ansatz that the variance of the steady-state probability distribution of constituent numbers in a population scales like the system size. This ansatz is used to expand the master equation in terms of a small parameter given by the inverse system size.

Specifically, let us write the Xi, the copy number of component i, as a sum of its "deterministic" value (a scaled-up concentration) and a random variable ξ, scaled by Ω1/2:

Xi=Ωϕi+Ω1/2ξi.

The probability distribution of X can then be rewritten in the vector of random variables ξ:

P(X,t)=P(Ωϕ+Ω1/2ξ)=Π(ξ,t).

Let us consider how to write reaction rates f and the step operator 𝔼 in terms of this new random variable. Taylor expansion of the transition rates gives:

fj(x)=fj(ϕ+Ω1/2ξ)=fj(ϕ)+Ω1/2i=1Nf'j(ϕ)ϕiξi+O(Ω1).

The step operator has the effect 𝔼f(n)f(n+1) and hence 𝔼f(ξ)f(ξ+Ω1/2):

i=1N𝔼Sij1Ω1/2iSijξi+Ω12ikSijSkj2ξiξk+O(Ω3/2).

We are now in a position to recast the master equation.

Π(ξ,t)tΩ1/2i=1NϕitΠ(ξ,t)ξi=Ωj=1R(Ω1/2iSijξi+Ω12ikSijSkj2ξiξk+O(Ω3/2))×(fj(ϕ)+Ω1/2if'j(ϕ)ϕiξi+O(Ω1))Π(ξ,t).

This rather frightening expression makes a bit more sense when we gather terms in different powers of Ω. First, terms of order Ω1/2 give

i=1NϕitΠ(ξ,t)ξi=i=1Nj=1RSijf'j(ϕ)Π(ξ,t)ξj.

These terms cancel, due to the macroscopic reaction equation

ϕit=j=1RSijf'j(ϕ).

The terms of order Ω0 are more interesting:

Π(ξ,t)t=j(ikSijf'jϕk(ξkΠ(ξ,t))ξi+12f'jikSijSkj2Π(ξ,t)ξiξk),

which can be written as

Π(ξ,t)t=ikAik(ξkΠ)ξi+12ik[BBT]ik2Πξiξk,

where

Aik=j=1RSijf'jϕk=(Sif)ϕk,

and

[BBT]ik=j=1RSijSkjf'j(ϕ)=[Sdiag(f(ϕ))ST]ik.

The time evolution of Π is then governed by the linear Fokker–Planck equation with coefficient matrices A and BBT (in the large-Ω limit, terms of O(Ω1/2) may be neglected, termed the linear noise approximation). With knowledge of the reaction rates f and stochiometry S, the moments of Π can then be calculated.

Applications to modeling stochastic reaction kinetics inside cells and higher order corrections

The linear noise approximation has become a popular technique for estimating the size of intrinsic noise in terms of coefficients of variation and Fano factors for molecular species in intracellular pathways. The second moment obtained from the linear noise approximation (on which the noise measures are based) are exact only if the pathway is composed of first-order reactions. However bimolecular reactions such as enzyme-substrate, protein-protein and protein-DNA interactions are ubiquitous elements of all known pathways; for such cases, the linear noise approximation can give estimates which are accurate in the limit of large reaction volumes. Since this limit is taken at constant concentrations, it follows that the linear noise approximation gives accurate results in the limit of large molecule numbers and becomes less reliable for pathways characterized by many species with low copy numbers of molecules.

A number of studies have elucidated cases of the insufficiency of the linear noise approximation in biological contexts by comparison of its predictions with those of stochastic simulations.[3][4] This has led to the investigation of higher order terms of the system size expansion that go beyond the linear approximation. These terms have been used to obtain more accurate moment estimates for the mean concentrations and for the variances of the concentration fluctuations in intracellular pathways. In particular, the leading order corrections to the linear noise approximation yield corrections of the conventional rate equations.[5] Terms of higher order have also been used to obtain corrections to the variances and covariances estimates of the linear noise approximation.[6][7] The linear noise approximation and corrections to it can be computed using the open source software intrinsic Noise Analyzer. The corrections have been shown to be particularly considerable for allosteric and non-allosteric enzyme-mediated reactions in intracellular compartments.

References

43 year old Petroleum Engineer Harry from Deep River, usually spends time with hobbies and interests like renting movies, property developers in singapore new condominium and vehicle racing. Constantly enjoys going to destinations like Camino Real de Tierra Adentro.

  1. 1.0 1.1 1.2 van Kampen, N. G. (2007) "Stochastic Processes in Physics and Chemistry", North-Holland Personal Library
  2. Elf, J. and Ehrenberg, M. (2003) "Fast Evaluation of Fluctuations in Biochemical Networks With the Linear Noise Approximation", Genome Research, 13:2475–2484.
  3. Hayot, F. and Jayaprakash, C. (2004), "The linear noise approximation for molecular fluctuations within cells", Physical Biology, 1:205
  4. Ferm, L. Lötstedt, P. and Hellander, A. (2008), "A Hierarchy of Approximations of the Master Equation Scaled by a Size Parameter", Journal of Scientific Computing, 34:127
  5. Grima, R. (2010) "An effective rate equation approach to reaction kinetics in small volumes: Theory and application to biochemical reactions in nonequilibrium steady-state conditions", The Journal of Chemical Physics, 132:035101
  6. Grima, R. and Thomas, P. and Straube, A.V. (2011), "How accurate are the nonlinear chemical Fokker-Planck and chemical Langevin equations?", The Journal of Chemical Physics, 135:084103
  7. Grima, R. (2012), "A study of the accuracy of moment-closure approximations for stochastic chemical kinetics", The Journal of Chemical Physics, 136: 154105