Long Li·Fan Song
RESEARCH PAPER
Entropic force between biomembranes
Long Li1,2·Fan Song1,2
Undulation force,an entropic force,stems from thermally excited fluctuations,and plays a key role in the essential interactions between neighboring surfaces of objects.Although the characteristics of the undulation force have been widely studied theoretically and experimentally,the distance dependence of the force,which constitutes its mostfundamentalcharacteristic,remains poorly understood. In this paper,first,we obtain a novelexpression forthe undulation force by employing elasticity and statisticalmechanics and prove it to be in good agreement with existing experimental results.Second,we clearly demonstrate that the two representative forms of the undulation force proposed by Helfrich and Freund were respectively the upper and lower bounds of the present expression when the separation between membranes is sufficiently small,which was intrinsically different from the existing results where Helfrich’s and Freund’s forms ofthe undulation force were only suitable for the intermediate and small separations.The investigations show that only in a sufficiently small separation does Helfrich’s result stand for the undulation force with a large wave number and Freund’s result express the force with a small wave number.Finally,a critical acting distance of the undulation force,beyond which the entropic force will rapidly decay approaching zero,is presented.
✉ Fan Song songf@lnm.imech.ac.cn
1State Key Laboratory of Nonlinear Mechanics(LNM)and Beijing Key Laboratory of Engineered Construction and Mechanobiology,Institute of Mechanics,Chinese Academy of Sciences,Beijing 100190,China
2School of Engineering Science,University of Chinese Academy of Sciences,Beijing 100049,China
Undulation force·Flexible membrane·Entropic force·Confined fluctuations
There always exist various attractive and repulsive forces that mediate between neighboring surfaces of objects,in which the van der Waals and undulation force are mainly responsible for the attractive and repulsive forces,respectively[1,2].Because the value of the undulation force is usually very small[2],its effect willefficiently emerge when the scales of objects are smaller than a micron.However,the undulation force usually plays a key role in the interactions between neighboring surfaces of microscale objects.Earlier studies showed that the undulation force governs the various cellular processes,for example,sperm-egg fusion and cell adhesion,binding-unbinding transition,and self-assembly[1-8];affects the structural stability of liquid crystals[9,10],surfactants[11],and DNA[12];regulates the mechanical behaviors of polymers[13],proteins[14],gels[15],and graphemes[16,17].In addition,the undulation force can affect the binding affinity of membrane-anchored proteins[18]and the self-assembly of polymers[19].
The concept and quantitative nature of the undulation force were proposed by Helfrich[20]in his original and pioneering work nearly four decades ago.Helfrich approximately treated a biomembrane as lots of very small elements that fluctuated independently,like the molecules of an ideal gas.He asserted that the undulation force essentially varies with c-3,where c is the separation between neighboring membranes[20].Although some assumptions and simplifications were introduced in Helfrich’s investigations[20,21],his results were stillsupported by succeeding studies,including theoretical[1,22-25]and experimental work[11,26],aswellas computational simulations[27,28].Recently,Freund[29]reexamined the entropic force underconditions in which some of Helfrich’s assumptions[20]were abandoned.Based on the theories of elasticity and statistical mechanics,Freund obtained a set of equations where the undulation force was satisfied.Itwas regretfulthathe gave no integralexpression ofthe undulation force because he did notdetermine the bounds of the transverse deflection of biomembranes.However,employing the asymptotic properties of the equations,Freund[29]found that the undulation force varied with c-1over a large range of separations.This result was in stark contrast to Helfrich’s well-accepted result,immediately triggered a series of disputes[2,29-35].More recently,many studies have presented deep discussions on the difference between the two results and examined the distance dependence of the undulation force.Auth and Gompper[32]and Hanlumyuang et al.[33]divided the acting distance of the undulation force into three regions.Based on Monte Carlo simulations,they proposed that Helfrich’s result remained valid forintermediate separations,while the undulation force f roughly satisfied f~ 1/(ca2)for small separations. Therefore,the undulation force was deemed to have a c-1dependence in small separations.Clearly,the role of the lattice constant,a,which discretized a membrane in the Monte Carlo simulations,was neglected in the distance dependence of the force.The transition length between the two regions was given as dtran≈a(kBT/κ)1/2,which wasalso associated with the discretized length;here,κ is the bending rigidity of the membrane.This implied thatdetermining the value ofthe undulation force heavily relies on the presetparametersin the simulations.For larger separations,Auth and Gompper[32]treated the entire membrane as a soft particle and obtained a c-1force law forseparations largerthan the crossoverlength,0.4 L(kBT/κ)1/2,while Hanlumyuang et al.[33]showed a c-ηdependence for the force,in which both the power η and the transition length to c-ηdependence were not integrally given.This is an indication that the distance dependence of the undulation force remains poorly understood.
In the present study,based on the theories of elasticity and statisticalmechanics,we obtain an exactintegralexpression of the undulation force with respect to the separation between membranes and show it to be in good agreement with existing experimentaldata.Analyzing the expression of the undulation force,we demonstrate thatthe two representative forms of the undulation force proposed by Helfrich and Freund are not in contradiction to each other.When the separation between membranes is sufficiently small,Helfrich’s result shows the undulation force on the membrane with a large wave number,while Freund’s result gives the undulation force on the membrane with a small wave number.The two forms of undulation force correspond respectively to the upper and lower bounds of the present result when the separation is sufficiently small.Finally,a critical acting distance ofthe undulation force,beyond which the entropic force will rapidly decay as it approaches zero,is presented.
To investigate the undulation force and its properties,we focus on a single flexible membrane confined between two parallel rigid planes of spacing 2c,as done by Helfrich and Servuss[20,21]and Freund[29].This is an appropriate model that can be used to study the interactions between membranes in a stack;in terms of a stack with a large number of membranes,the behavior of any single membrane far from eitherend ofthe stack exhibits reflective symmetry with respectto itsreference plane,and the behaviorofneighboring membranes also exhibits reflective symmetry with respect to a plane midway between the reference planes of the two membranes[20,21,29].We assume that the membrane satisfies the periodic boundary conditions on the edges and its reference plane occupies the portion 0≤x≤L,0≤y≤L of the xy-plane(Fig.1).
The transverse deflection of the membrane related to the reference plane is assumed to be h(x,y),which obviously satisfies the confined condition:
We write the transverse deflection as a complex wave[20,36]:
where i is the imaginary unit,q=(π/L)(m,n)and r=(x,y)are the wave and coordinate vectors of the membrane,respectively,and the amplitude of the wave satisfies h-q= h∗q,in which the star denotes complex conjugation.Here m and n are integral numbers,and physically,|m|=L/λxand |n|=L/λyrespectively correspond to the wave numbers of the thermal fluctuation modes of the membrane in the x-and y-directions,and λxand λyare the wavelengths in the xand y-directions,respectively.Further,we extend h(r)to the domain of-L≤x,y≤L such that h(r)satisfies Eq.(2)in0≤x≤L,0≤y≤L,and h(r)=0 otherwise.Thus,the amplitude of the wave is given by the Fourier integral and substituting Eq.(1) into Eq.(3)yields the bounds of the amplitudes
Fig.1 Schematic diagram showing a thermally fluctuating square biomembrane with dimension of L×L confined between two rigid planes of separation 2c.h(x,y)is the transverse deflection of the membrane related to the reference plane positioned in xy-plane of coordinates
The total elastic bending energy of the membrane is written
where ε=(κ/2)(∂2h/∂x2+∂2h/∂y2)2denotes the elastic bending energy per unit area of the membrane[20].
According to the theory of statistical mechanics,the thermodynamic partition function of a membrane is
where β=1/(kBT),kBis the Boltzmann constant,T is the absolute temperature,is the error function,and ωmnis a dimensionless factor
Based on Eq.(6),the free energy of the membrane is expressed as
Thus,the entropic force acting on the membrane is obtained as
where
Obviously,Eq.(9)gives an integral expression of the undulation force exerted on a membrane and shows that the distance dependence of the force is strongly nonlinear and very complex,which is intrinsically different from existing theoretical and computational results.This is because ωmnin Eq.(9)explicitly includes the separation between membranes,c,as indicated in Eq.(7).Simultaneously,Eq.(9)is also dependent strongly on the wave numbers of the membrane,m and n.
In fact,the thermally excited membrane fluctuation stems intrinsically from the stimulation of Brownian motion of solvent molecules,which results in there being no preferential orientation of the undulation force acting in the plane of the membrane with the thermally excited fluctuation.Therefore,the wavelength of the waves generated by thermal excited fluctuation in the x-and y-directions in the plane of the membrane itself should be equal statistically to one another.In terms of the square membrane studied here,the wave numbers of the membrane in the x-and y-directions,m and n,should be equal statistically to one another.
According to Eq.(7),when m=n,ωmnis written as
Substituting Eq.(11)into Eq.(9),the undulation force is written as
where k is associated with the wave number of the membrane and m=n=2k-1.With an increase in k,the undulation force in Eq.(12)also increases monotonically. This is an indication thatthe wave numberyielded in a membrane plays a key role in the undulation force generated on the membrane.In addition,because Φ(ωmn)is a monotonically decreasing function with respect to ωmnfrom Eq.(10),Eq.(12)in fact stands for the minimum curve of Eq.(9)and appropriately expresses the undulation force exerted on a square membrane.
Comparing the results of Eq.(12)with the existing experimental data[26],we find that the present results are in good agreement with the experimental results(Fig.2).
Fig.2 Computational plots showing distance dependence of undulation force;solid lines:results ofEq.(12)for T=300 Kand L=1.0μm;points are derived from the experimental data from Ref.[24];inset displays detail of comparison between present and experimental results
Fig.3 Computational plots showing lower and upper bounds of undulation force when separation is sufficiently small(here the separation is coarsely three orders of magnitude smaller than the side length of the membrane)for a membrane with κ=5.0 kBT and L=1.0μm.The lower(slop=-1)and upper(slop=-3)lines correspond respectively to Freund’s and Helfrich’s results
We now investigate the two extreme cases of the undulation force in Eq.(12).First,when a membrane only generates a single wave underthe undulation force,the wavelength ofthe wave will be at the maximum value,λx=λy=λmax=L. Thus,the wave number of the membrane is at its minimum value,mmin=nmin=kmin=L/λmax=1.At this time,the undulation force stands for the minimum value of Eq.(12),which is expressed as
In particular,if the variation ω is sufficiently small,ω≪1,i.e.,the separation between the membranes is very small,c≪L,then Eq.(13)is reduced to
Equation(14)shows that the undulation force varies with c-1when c≪ L,which is identical to the result given by Freund[29]and is in agreement with the results of Auth and Gompper[32]and Hanlumyuang et al.[33]for small separations.Obviously,Eq.(14)forms the lower bound of Eq.(12)when the separation is sufficiently small(Fig.3).
Note thatifthe membrane is perfectly rigid,its wave number is equal to one.Equation(13)obviously includes the undulation force exerted on the rigid membrane.
Second,we considerthatthe dimensions ofthe membrane approach a single molecularscale.In this case,the membrane is similar to a single molecule that keeps random thermal vibrations in the direction normal to the reference plane of the membrane.Atthis time,both the wavelength ofthe membrane in the x-and y-directions are at their minimum values, λx=λy=λmin,and the energy of the thermal motion in a single direction is roughly 1/(2β).Therefore,the maximum value of the wave number is mmax=nmax=L/λmin. According to Eqs.(4)and(5),the value of the wave vector is and the maximum amplitude of the wave satisfies,and the elastic bending energy of the membrane is calculated asBy equating the elastic bending energy to the energy of thermal motion,we obtain the minimum wavelength of the thermal fluctuation of the membrane:
In termsofthe membrane withthe given edgesof L×L,we note that its maximum wave numbers are mmax=nmax= L/λmin=2kmax-1.Substituting Eq.(15)into Eq.(12)yields the maximum value of the undulation force,
where kmax≫1 is used in Eq.(16).
If the separation is sufficiently small,ω≪1 or c≪ L,Eq.(16)is written
Over the separation range of c≪ L,Eq.(17)clearly indicates that the undulation force varies with c-3.Equation(17)can readily be written in the form of entropic pressure,pmax=fmax/L2=1/(16κβ2c3),which is in agreementwith the resultgiven by Helfrich and Servuss[21]. Obviously,Eq.(17)forms the upper bound of the undulation force in Eq.(12),as shown in Fig.3.
Fig.4 Computational plots showing critical acting distance of undulation force,ccrit.The curves stand for the undulation forces of the membrane with the same wave number and different bending rigidity for T=300K,L=1.0μm,wherecorrespond to the different critical distances with the different bending rigidities of membranes.Insert:same data in a double logarithmic coordinate
As stated earlier,the two forms of the undulation force proposed separately by Helfrich[20]and Freund[29]are not contradictory to each other and respectively stand for the upper and lower bounds of the presented result under the condition that the separation is sufficiently small.In fact,Helfrichshowedtheundulationforceaffectingthemembrane with the large wave number,while Freund gave the undulationforceactingonthemembranewithasmallwavenumber. Obviously,the result here is intrinsically different from the explanations of the two undulation forces given by Auth and Gompper[32]and Hanlumyuang et al.[33].
Finally,if the separation between membranes is sufficiently large,i.e.,ω≫1,then the value of the undulation force,from Eq.(12),will approach zero.In fact,according to the nature of the error function,when ω≥2.0,the error functionwillrapidlyapproach1,theerrorofwhichis<0.5%. Because Φ(ωmn)in Eq.(10)is a monotonically decreasing functionwithrespecttoωmn,theundulationforceinEq.(12)will rapidly approach zero.According to Eq.(11),we obtain the distance
Equation(18)shows that there exists a critical separation on the undulation force.Once the separation between membranes is larger than the critical length,the undulation force generated between the membranes will decay and rapidly approach zero(Fig.4).
Based on the theories of elasticity and statistical mechanics,an exact integral expression of the undulation force is given in this study.The present result is proved to be in good agreement with existing experiments.Based on the expression of the undulation force,we demonstrate that Helfrich’s and Freund’s results stand respectively for undulation forces on membranes with large and small wave numbers and correspond respectively to the upper and lower bounds of the presented result when the separation between membranes is sufficientlysmall.Acriticaldistancebetweenmembraneson which the undulation force effectively acts is presented.
Acknowledgments The project was supported by the programs in the National Natural Science Foundation of China(Grants 11232013 and 11472285).L.LithanksL.B.FreundandR.Lipowskyforinsightfuldiscussions.F.SongisverygratefultoY.L.BaiofStateKeyLaboratoryof Nonlinear Mechanics and F.J.Ke of Beijing University of Aeronautics and Astronautics for helpful discussions.
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11 March 2016/Revised:5 May 2016/Accepted:12 May 2016/Published online:11 August 2016
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