Guo Zhongyuan, DeLoid Glen M, Cao Xiaoqiong, Bitounis Dimitrios, Sampathkumar Kaarunya, Woei Ng Kee, Joachim Loo Say Chye, Philip Demokritou
Center for Nanotechnology and Nanotoxicology, Department of Environmental Health, Harvard T. H. Chan School of Public Health, Boston, MA 02115, USA.
School of Materials Science and Engineering, Nanyang Technological University 50 Nanyang Avenue 639798, Singapore, Singapore.
Environ Sci Nano. 2021 Sep 1;8(2):2554-2568. doi: 10.1039/d1en00233c. Epub 2021 Jul 20.
Nanoscale materials derived from natural biopolymers like cellulose and chitosan have many potentially useful agri-food and oral drug delivery applications. Because of their large and potentially bioactive surface areas and other unique physico-chemical properties, it is essential when evaluating their toxicological impact to assess potential effects on the digestion and absorption of co-ingested nutrients. Here, the effects of cellulose nanofibers (CNF), cellulose nanocrystals (CNC), and chitosan nanoparticles (Chnp) on the digestion and absorption of carbohydrates were studied. Starch digestion was assessed by measuring maltose released during simulated digestion of starch solutions. Glucose absorption was assessed by measuring translocation from the resulting digestas across an in vitro transwell tri-culture model of the small intestinal epithelium and calculating the area under the curve increase in absorbed glucose, analogous to the glycemic index. At 1% w/w, CNF and Chnp had small but significant effects (11% decrease and 14% increase, respectively) and CNC had no effect on starch hydrolysis during simulated digestion of a 1% w/w rice starch solution. In addition, at 2% w/w CNC had no effect on amylolysis in 1% solutions of either rice, corn, or wheat starch. Similarly, absorption of glucose from digestas of starch solutions (i.e., from maltose), was unaffected by 1% w/w CNF or CNC, but was slightly increased (10%, p<0.05) by 1% Chnp, possibly due to the slightly higher maltose concentration in the Chnp-containing digestas. In contrast, all of the test materials caused sharp increases (~1.2, 1.5, and 1.6 fold for CNC, CNF, and Chnp, respectively) in absorption of glucose from starch-free digestas spiked with free glucose at a concentration corresponding to complete hydrolysis of 1% w/w starch. The potential for ingested cellulose and chitosan nanomaterials to increase glucose absorption could have important health implications. Further studies are needed to elucidate the mechanisms underlying the observed increases and to evaluate the potential glycemic effects in an intact in vivo system.
源自纤维素和壳聚糖等天然生物聚合物的纳米级材料在农业食品和口服药物递送方面有许多潜在的应用。由于它们具有大的且可能具有生物活性的表面积以及其他独特的物理化学性质,在评估其毒理学影响时,评估对同时摄入的营养物质消化和吸收的潜在影响至关重要。在此,研究了纤维素纳米纤维(CNF)、纤维素纳米晶体(CNC)和壳聚糖纳米颗粒(Chnp)对碳水化合物消化和吸收的影响。通过测量淀粉溶液模拟消化过程中释放的麦芽糖来评估淀粉消化。通过测量消化产物跨小肠上皮体外Transwell三培养模型的转运情况,并计算吸收葡萄糖曲线下面积的增加量(类似于血糖指数)来评估葡萄糖吸收。在1% w/w时,CNF和Chnp对1% w/w大米淀粉溶液模拟消化过程中的淀粉水解有小但显著的影响(分别降低11%和增加14%),而CNC没有影响。此外,在2% w/w时,CNC对1%的大米、玉米或小麦淀粉溶液中的淀粉分解没有影响。同样,淀粉溶液消化产物(即来自麦芽糖)中葡萄糖的吸收不受1% w/w CNF或CNC的影响,但1% Chnp使其略有增加(10%,p<0.05),这可能是由于含Chnp的消化产物中麦芽糖浓度略高。相比之下,所有测试材料都使添加了与1% w/w淀粉完全水解相对应浓度的游离葡萄糖的无淀粉消化产物中的葡萄糖吸收大幅增加(CNC、CNF和Chnp分别约增加1.2、1.5和1.6倍)。摄入的纤维素和壳聚糖纳米材料增加葡萄糖吸收的可能性可能对健康有重要影响。需要进一步研究以阐明观察到的增加背后的机制,并在完整的体内系统中评估潜在的血糖影响。
