TY - JOUR
T1 - Molecular structure and linear-non linear rheology relation of rice starch during milky, dough, and mature stages
AU - Ranathunga, Ashoka
AU - Suwannaporn, Prisana
AU - Kiatponglarp, Worawikunya
AU - Wansuksri, Rungtiva
AU - Sagis, Leonard M.C.
PY - 2023/7/15
Y1 - 2023/7/15
N2 - Immature rice has potential to be used as healthy food. The relation between molecular structure and rheological properties was investigated. The lamellar repeating distance (8.42–8.63 nm) and crystalline thickness (4.60–4.72 nm) were not different among stages indicating a complete lamellar structure even at early stage. The relative crystallinity was higher in dough (39.62 %) than milky (36.69 %) and mature starch (35.22 %) caused by molecular structure, amylose, and amylose-lipid complex. The short amylopectin branched chains (A and B1) in dough starch were easily entangled resulted in higher Payne effect and elastic dominant. Dough starch paste exhibited higher G′Max (738 Pa) than milky (685 Pa) and mature (645 Pa) starch. In a non-linear viscoelastic regime, small strain hardening was found in milky and dough starch. Mature starch showed the highest plasticity and shear thinning at high-shear strains as the long-branched chains (B3) microstructure was disrupted, disentangled, followed by chain orientation along shear.
AB - Immature rice has potential to be used as healthy food. The relation between molecular structure and rheological properties was investigated. The lamellar repeating distance (8.42–8.63 nm) and crystalline thickness (4.60–4.72 nm) were not different among stages indicating a complete lamellar structure even at early stage. The relative crystallinity was higher in dough (39.62 %) than milky (36.69 %) and mature starch (35.22 %) caused by molecular structure, amylose, and amylose-lipid complex. The short amylopectin branched chains (A and B1) in dough starch were easily entangled resulted in higher Payne effect and elastic dominant. Dough starch paste exhibited higher G′Max (738 Pa) than milky (685 Pa) and mature (645 Pa) starch. In a non-linear viscoelastic regime, small strain hardening was found in milky and dough starch. Mature starch showed the highest plasticity and shear thinning at high-shear strains as the long-branched chains (B3) microstructure was disrupted, disentangled, followed by chain orientation along shear.
KW - Immature
KW - Linear rheology
KW - Nonlinear rheology
KW - Rice starch
KW - Starch structure
KW - Structure-property relation
U2 - 10.1016/j.carbpol.2023.120812
DO - 10.1016/j.carbpol.2023.120812
M3 - Article
AN - SCOPUS:85149853929
SN - 0144-8617
VL - 312
JO - Carbohydrate Polymers
JF - Carbohydrate Polymers
M1 - 120812
ER -