CKD is a global health problem affecting more than 9% of the world population and a high US prevalence of 15%, associated with high healthcare costs, morbidity, and mortality. The increased risk for CKD death has been attributed to chronic inflammation, oxidative stress, malnutrition, high prevalence of hypertension, diabetes, and CVD. A declining kidney function accumulates uremic retention molecules, notably indoxyl sulfate (IS), p-Cresyl sulfate (PCS), trimethylamine-N-Oxide (TMAO), blood urea nitrogen (BUN), and creatinine, known to be associated with a progressive decline of kidney function, mineral bone disorder, CVD, and increased mortality [38]. The interaction between gut microbiota and CKD is a bidirectional relationship as CKD causes a shift of healthy gut microbiome composition to a state of imbalance between healthy and pathogenic bacteria termed gut dysbiosis. This gut dysbiosis disrupts intestinal epithelial integrity, enhances inflammatory and immunological processes due to endotoxemia, gut-derived uremic toxins, and acidosis which leads to progression and complications [30]. Other contributors to the persistence of dysbiosis include decreased consumption of dietary fibers, frequent antibiotic use, slow colonic transit time, metabolic acidosis, volume overload, intestinal wall edema, and oral iron [30,39]. An experimental finding of dietary fiber effect on dysbiosis in mouse CKD model fed with high amylose resistant starch diet showed decreased microbial diversity, increased ratio of beneficial Bifidobacteria genera and Bacteroidetes to Firmicutes phyla [39]. A similar finding in human CKD stage 3–4 showed increased Bifidobacteria and Lactobacillus species counts after short-term lactulose supplementation [40]. Carefully selected dietary fiber administration was found appropriate and effective in reducing uremic toxins in CKD patients with fibers containing resistant starch, arabino-xylo-oligosaccharide, gum acacia, and Xylo-oligosaccharide [41]. In another study of hemodialysis (HD) patients, resistant starch supplementation reduced plasma indoxyl sulfate (IS) levels, while an oligofructose enriched inulin diet reduced the serum PCS levels [42]. These observations on reducing plasma levels of uremic toxins following interventions with different dietary fiber types were attributed to differences in the effectiveness of modulating gut microbiome to produce sufficient SCFA to restore gut barrier integrity [43]. Hence, studies have recommended that CKD patients should increase adequate consumption of dietary multifiber and vegetable-based diet to restore intestinal integrity, improve metabolic profile, prevent comorbidities, and retard CKD progression [44]. Due to diet restrictions in CKD patients, supplementary dietary multifiber is a supportive nutritional therapy in all CKD stages to enhance the removal of uremic toxins linked to cardiovascular complications [45]. High fiber intake as a recommended renal diet in CKD remains a challenge due to concerns of high potassium and phosphorus levels. To overcome these fears, fiber from natural foods sources (fruits, vegetables, whole grains) as plant-based diets should be preferred due to better nutrient composition and relatively lower bioavailability of potassium and phosphorus [46].