1 |
Smith M E, Morton D G. The Digestive System[M]. 2nd ed. Singapore: Elsevier Pte Ltd., 2010.
|
2 |
Lim Y F, de Loubens C, Love R J, et al. Flow and mixing by small intestine villi[J]. Food Funct., 2015, 6: 1787-1795.
|
3 |
Lentle R G, Janssen P W M, de Loubens C, et al. Mucosal microfolds augment mixing at the wall of the distal ileum of the brushtail possum[J]. Neurogastroenterol. Motil., 2013, 25: e700-881-888.
|
4 |
Wang Y X, Brasseur J G, Banco G G, et al. A multiscale lattice Boltzmann model of macro- to micro-scale transport, with applications to gut function[J]. Phil. Trans. R. Soc. A, 2010, 368: 2863-2880.
|
5 |
Wang Y X, Brasseur J G. Three-dimensional mechanisms of macro-to-micro-scale transport and absorption enhancement by gut villi motions[J]. Phys. Rev. E, 2017, 95: 062412-1-8.
|
6 |
Du P, Paskaranandavadivel N, Angeli T R, et al. The virtual intestine: in silico modeling of small intestinal electrophysiology and motility and the applications[J]. WIREs System Biology and Medicine, 2016, 8: 69-85.
|
7 |
Stoll B R, Batycky R P, Leipold H R, et al. A theory of molecular absorption from the small intestine[J]. Chem. Eng. Sci., 2000, 55: 473-489.
|
8 |
Grivel M L, Ruckebusch Y. The propagation of segmental contractions along the small intestine[J]. J. Physiol., 1972, 227: 611-625.
|
9 |
Avvari R K. Effect of local longitudinal shortening on the transport of luminal contents through small intestine[J]. Acta Mechanica Sinica, 2019, 35: 45-60.
|
10 |
Love R J, Lentle R G, Asvarujanon P, et al. An expanded finite element model of the intestinal mixing of digesta[J]. Food Dig., 2013, 4: 26-35.
|
11 |
Tharakan A, Norton I T, Fryer P J, et al. Mass transfer and nutrient absorption in a simulated model of small intestine[J]. Journal of Food Science, 2010, 75: E339-E346.
|
12 |
Tharakan A. Modeling of physical and chemical processes in the small intestine[D]. UK: University of Birmingham, 2008.
|
13 |
Sinnott M D, Cleary P W, Harrison S M. Peristaltic transport of a particulate suspension in the small intestine[J]. Applied Mathematical Modeling, 2017, 44: 143-159.
|
14 |
Lentle R G, de Loubens C. A review of mixing and propulsion of chyme in the small intestine: fresh insights from new methods[J]. J. Comp. Physiol. B, 2015, 185: 369-387.
|
15 |
de Loubens C, Lentle R G, Love R J, et al. Fluid mechanical consequences of pendular activity, segmentation and pyloric outflow in the proximal duodenum of the rat and the guinea pig[J]. J. R. Soc. Interface, 2013, 10: 20130027-1-12.
|
16 |
de Loubens C, Lentle R G, Hulls C, et al. Characterisation of mixing in the proximal duodenum of the rat during longitudinal contractions and comparison with a fluid mechanical model based on spatiotemporal motility data[J]. PLOS One, 2014, 9: e95000-1-6.
|
17 |
Lim Y F, Lentle R G, Janssen P W M, et al. Determination of villous rigidity in the distal ileum of the possum (trichosurus vulpecula)[J]. PLOS One, 2014, 9: e100140-1-11.
|
18 |
Lim Y F, Williams M A K, Lentle R G, et al. An exploration of the microrheological environment around the distal ileal villi and proximal colonic mucosa of the possum (Trichosurus vulpecula)[J]. J. R. Soc. Interface, 2013, 10: 20121008-1-11.
|
19 |
Lentle R G, Janssen P W M. The Physical Processes of Digestion[M]. New York: Springer Science, 2011.
|
20 |
Lim Y F. Factors influencing mixing and mass transfer in the small intestine [D]. New Zealand: Massey University, 2015.
|
21 |
Cani P D. Human gut microbiome: hopes, threats and promises [J]. Gut, 2018, 67: 1716-1725.
|
22 |
Wang D D, Hu F B. Precision nutrition for prevention and management of type 2 diabetes[J]. Lancet Diabetes Endocrinol., 2018, 6: 416-426.
|
23 |
秦逸凡, 肖杰, 陈晓东. 血糖预测生理模型及化工建模策略[J]. 化工进展, 2019, 38(1): 545-555.
|
|
Qin Y F, Xiao J, Chen X D. Blood glucose prediction based on physiological and chemical reactor models[J]. Chemical Industry and Engineering Progress, 2019, 38(1): 545-555.
|
24 |
Liu M H, Xiao J, Chen X D. A soft-elastic reactor (SER) inspired by the animal upper digestion tract[J]. Chemical Engineering and Technology, 2018, 41: 1051-1056.
|
25 |
刘明慧, 邹超, 肖杰, 等. 基于仿生学的柔性反应器[J]. 化工学报, 2018, 69(1): 414-422.
|
|
Liu M H, Zou C, Xiao J, et al. Soft-elastic bionic reactor[J]. CIESC Journal, 2018, 69(1): 414-422.
|
26 |
Xiao J, Zou C, Liu M H, et al. Mixing in a soft-elastic reactor (SER) characterized using an RGB based image analysis method[J]. Chem. Eng. Sci., 2018, 181: 272-285.
|
27 |
Delaplace G, Gu Y Y, Liu M H, et al. Homogenization of liquids inside a new soft elastic reactor: revealing mixing behavior through dimensional analysis[J]. Chem. Eng. Sci., 2018, 192: 1071-1080.
|
28 |
Li C Y, Xiao J, Zhang Y, et al. Mixing in a soft-elastic reactor (SER): a simulation study[J]. Can. J. Chem. Eng., 2019, 97: 676-686.
|
29 |
Moxon T E, Gouseti O, Bakalis S. In silico modeling of mass transfer & absorption in the human gut[J]. J. Food Eng., 2016, 176: 110-120.
|
30 |
Zhang Y N, Wu P, Jeantet R, et al. How motility can enhance mass transfer and absorption in the duodenum: taking the structure of the villi into account[J]. Chem. Eng. Sci., 2020, 213: 115406-1-13.
|
31 |
COMSOL Multiphysics® v.5.4 [EB/OL].[2019]. .
|
32 |
Tortora G J, Derrickson B H. Principles of Anatomy and Physiology[M]. 15th ed. US: Wiley, 2018.
|
33 |
Guseinov T S, Guseinova S T. Effect of dehydration on morphogenesis of the lymphatic network and immune structures in the small intestine[J]. Bull. Exp. Biol. Med., 2008, 145: 755-757.
|
34 |
Marieb E N, Keller S M. Essentials of Human Anatomy & Physiology[M]. 12th ed. US: Pearson, 2017.
|
35 |
Leiper J B. Fate of ingested fluids: factors affecting gastric emptying and intestinal absorption of beverages in humans[J]. Nutrition Reviews, 2015, 73: 57-72.
|