1.
Protein blend ingestion before allogeneic stem cell transplantation improves protein-energy malnutrition in patients with leukemia.
Ren, G, Zhang, J, Li, M, Yi, S, Xie, J, Zhang, H, Wang, J
Nutrition research (New York, N.Y.). 2017;:68-77
Abstract
Severe protein-energy malnutrition (PEM) and skeletal muscle wasting are commonly observed in patients with acute leukemia. Recently, the ingestion of a soy-whey protein blend has been shown to promote muscle protein synthesis (MPS). Thus, we tested the hypothesis that the ingestion of a soy-whey blended protein (BP) may improve the PEM status and muscle mass in acute leukemia patients. In total, 24 patients from the same treatment group were randomly assigned to the natural diet plus soy-whey blended protein (BP) group and the natural diet only (ND) group. Our data showed that protein and energy intake decreased significantly (P < .05) after transplantation in both groups. In the absence of the BP intervention, dramatic decreases in muscle-related indicators (i.e., anthropometric variables, muscle strength and serum protein) were observed in the majority (>50%) of the patients. However, 66% of the patients who ingested the BP before transplantation showed obvious increases in arm muscle area. The gripping power value (△post-pre or △post-baseline) was significantly higher in the BP group than in the ND group (P < .05). The ingestion of the BP also increased the levels of serum albumin, globulin and serum total protein to different extents. Notably, the average time to stem cell engraftment was significantly shorter for patients in the BP group (12.2 ± 2.0 days) than for patients in the ND group (15.1 ± 2.9 days). Collectively, our data supported that soy-whey protein can improve PEM status and muscle mass in leukemia patients.
2.
Effects of plasticization and shear stress on phase structure development and properties of soy protein blends.
Chen, F, Zhang, J
ACS applied materials & interfaces. 2010;(11):3324-32
Abstract
In this study, soy protein concentrate (SPC) was used as a plastic component to blend with poly(butylene adipate-co-terephthalate) (PBAT). Effects of SPC plasticization and blend composition on its deformation during mixing were studied in detail. Influence of using water as the major plasticizer and glycerol as the co-plasticizer on the deformation of the SPC phase during mixing was explored. The effect of shear stress, as affected by SPC loading level, on the phase structure of SPC in the blends was also investigated. Quantitative analysis of the aspect ratio of SPC particles was conducted by using ImageJ software, and an empirical model predicting the formation of percolated structure was applied. The experimental results and the model prediction showed a fairly good agreement. The experimental results and statistic analysis suggest that both SPC loading level and its water content prior to compounding had significant influences on development of the SPC phase structure and were correlated in determining the morphological structures of the resulting blends. Consequently, physical and mechanical properties of the blends greatly depended on the phase morphology and PBAT/SPC ratio of the blends.