Gut microbiota composition influences outcomes of skeletal muscle nutritional intervention via blended protein supplementation in posttransplant patients with hematological malignancies.

BACKGROUND: Skeletal muscle atrophy is an important and independent predictor of survival after hematopoietic stem cell transplantation (HSCT). Our previous study found that soy-whey blended protein (SWP) can improve muscle mass in acute leukemia patients. OBJECTIVE: We aimed to explore potential factors that influence muscle outcomes after nutritional intervention. METHODS: In this case-control study, 13 patients who received HSCT and failed to improve muscle function within half a year were included. After two months of SWP intervention, the subjects were divided into two groups (MSI: muscle status improved; MNI: muscle status not improved). 16S rDNA sequencing, principal coordinate analysis (PCoA) and the PICRUSt algorithm were used to analyze the composition, structure and function of the intestinal microbiota between the groups. This study was registered in the Chinese Clinical Trial Registry (ChiCTR 1800017765). RESULTS: SWP significantly improved muscle status (muscle area: from 330.4 mm2 to 384.8 mm2, p = 0.02; muscle strength: from 19.2 kg to 21.3 kg, p = 0.04). However, there were a small number of subjects whose muscle status was not effectively improved. After SWP intervention, the diversity (Shannon: from 1.7 to 3.8, p = 0.01; Simpson: from 0.6 to 0.8, p = 0.015) of the intestinal microbiota in the MSI group increased significantly, whereas that in the MNI group did not. Principal component analysis (PCA) revealed separate groupings of the microbiota of the Baseline-MSI and Endpoint-MSI time points in the MSI group. Opposite patterns of microbial abundance change were found between the MSI group (75% of changed genera were increased) and the MNI group (80% of changed genera were decreased). Three bacterial taxa (negative correlation: Streptococcus; positive correlations: Ruminococcus and Veillonella) were significantly related to muscle improvement outcomes. Both pentose phosphate (p = 0.048) and amino acid biosynthesis (p = 0.039), which are related to muscle metabolism, were found to be significantly changed in the MSI group through PICRUSt algorithm prediction. CONCLUSIONS: Our results suggest that the intestinal microbiota plays important roles in the regulation of muscle metabolism.

Protein blend ingestion before allogeneic stem cell transplantation improves protein-energy malnutrition in patients with leukemia.

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.

Ingestion of soy-whey blended protein augments sports performance and ameliorates exercise-induced fatigue in a rat exercise model.

This study sought to determine the effects of soy-whey blended protein supplementation on sports performance and related biochemical parameters after long-term training. After a week of adaptation, eighteen 6-week-old male Wistar rats were randomly assigned to 3 groups: the standard chow diet plus whey protein (Whey) group, the standard chow diet plus soy-whey blended protein (BP) group and the standard chow diet only (control) group. Each group included 6 rats for the seven-week experiment. Before the experiment, the baseline values of body weight, grasping force and time to exhaustion due to the loaded-swimming test were recorded for each group. During the experimental period, all rats performed the loaded-swimming test until exhaustion five days each week. The results showed that the mean maximum grasping force of the BP group significantly increased between the 5th and the 7th week (p < 0.05) compared with the other groups. The ingestion of blended protein for 7 weeks significantly increased the mean time to exhaustion due to swimming by 1.5-fold and 1.2-fold compared with the control and Whey groups, respectively. The plasma levels of leucine, isoleucine and valine were significantly higher at 60 min after the blended protein intervention compared with the Whey and control interventions (p < 0.05). Furthermore, the ingestion of soy-whey blended protein enhanced the activities of lactate dehydrogenase and superoxide dismutase and decreased the levels of malondialdehyde in serum. These results collectively suggest that soy-whey blended protein ingestion with resistance exercise can improve sports performance and ameliorate exercise-induced fatigue in rats.