2011
DOI: 10.1002/bip.21723
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Liquid crystal models of biological materials and silk spinning

Abstract: A review of thermodynamic, materials science, and rheological liquid crystal models is presented and applied to a wide range of biological liquid crystals, including helicoidal plywoods, biopolymer solutions, and in vivo liquid crystals. The distinguishing characteristics of liquid crystals (self-assembly, packing, defects, functionalities, processability) are discussed in relation to biological materials and the strong correspondence between different synthetic and biological materials is established. Biologi… Show more

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Cited by 53 publications
(60 citation statements)
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“…The main objective is to identify material conditions that lead to a biologically relevant power spectrum with a well-defined resonant peak and Q-factor less than one (Q(ω) < 1), using the transfer function methodology of § §4 and 5. Table 2 figure 5; the other modes {II, IV, VI} corresponding to stiff (large k) membranes are not biologically relevant [18] either because they do not form power peaks or because Q(ω) > 1 (store more membrane elastic energy than inject momentum into the fluids). In the case when the inertial mechanisms are neglected, De 1, the real Re[F D (ω)] and imaginary Im[F D (ω)] parts of the transfer function behave as would be expected for a simple viscoelastic system displaying a single peak and two asymptotic plateaus separated by a power-law region (PLR).…”
Section: Numerical Resultsmentioning
confidence: 99%
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“…The main objective is to identify material conditions that lead to a biologically relevant power spectrum with a well-defined resonant peak and Q-factor less than one (Q(ω) < 1), using the transfer function methodology of § §4 and 5. Table 2 figure 5; the other modes {II, IV, VI} corresponding to stiff (large k) membranes are not biologically relevant [18] either because they do not form power peaks or because Q(ω) > 1 (store more membrane elastic energy than inject momentum into the fluids). In the case when the inertial mechanisms are neglected, De 1, the real Re[F D (ω)] and imaginary Im[F D (ω)] parts of the transfer function behave as would be expected for a simple viscoelastic system displaying a single peak and two asymptotic plateaus separated by a power-law region (PLR).…”
Section: Numerical Resultsmentioning
confidence: 99%
“…which coincides with E H , and gives 4k c = (K 1 + 8K 24 ),k c = −2K 24 ; the surface gradient is given by the tangential projection of the total gradient: ∇ s (·) ≡ I s · ∇(·), I s = I − kk, since thin layers and membranes behave like LCs, membranes should also exhibit flexoelectricity or couplings between polarization and bending [1][2][3][4]7,11,[17][18][19]. Figure 2 shows a schematic of flexoelectric polarization in rod-like and banana-like molecules and the corresponding membrane flexoelectric polarization; as noted above the physics and modelling are affected by identifying the director field n with the membrane normal k. Using the same approach as above, equation (1.4) gives the membrane polarization P due to membrane bending (∇ s · k): 10) where c f is the membrane flexoelectric coefficient, as indeed found experimentally [4].…”
Section: (B) Materialsmentioning
confidence: 96%
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