3D Electron Tomography of Pretreated Biomass Informs Atomic Modeling of Cellulose Microfibrils

Fundamental insights into the macromolecular architecture of plant cell walls will elucidate new structure–property relationships and facilitate optimization of catalytic processes that produce fuels and chemicals from biomass. Here we introduce computational methodology to extract nanoscale geometr...

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Bibliographic Details
Published in:ACS nano 2013-09, Vol.7 (9), p.8011-8019
Main Authors: Ciesielski, Peter N, Matthews, James F, Tucker, Melvin P, Beckham, Gregg T, Crowley, Michael F, Himmel, Michael E, Donohoe, Bryon S
Format: Article
Language:English
Subjects:
Architecture
Biomass
Cell Membrane - chemistry
Cell Membrane - ultrastructure
Cellulose
Computation
Computer Simulation
Curvature
Electron Microscope Tomography - methods
Fibrillar Collagens - chemistry
Fibrillar Collagens - ultrastructure
Imaging, Three-Dimensional - methods
Mathematical models
Models, Chemical
Models, Molecular
Molecular Imaging - methods
Nanostructure
Protein Conformation
Sulfates
Walls
Zea mays - chemistry
Zea mays - ultrastructure
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Summary:Fundamental insights into the macromolecular architecture of plant cell walls will elucidate new structure–property relationships and facilitate optimization of catalytic processes that produce fuels and chemicals from biomass. Here we introduce computational methodology to extract nanoscale geometry of cellulose microfibrils within thermochemically treated biomass directly from electron tomographic data sets. We quantitatively compare the cell wall nanostructure in corn stover following two leading pretreatment strategies: dilute acid with iron sulfate co-catalyst and ammonia fiber expansion (AFEX). Computational analysis of the tomographic data is used to extract mathematical descriptions for longitudinal axes of cellulose microfibrils from which we calculate their nanoscale curvature. These nanostructural measurements are used to inform the construction of atomistic models that exhibit features of cellulose within real, process-relevant biomass. By computational evaluation of these atomic models, we propose relationships between the crystal structure of cellulose Iβ and the nanoscale geometry of cellulose microfibrils.
ISSN:1936-0851
1936-086X
DOI:10.1021/nn4031542