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Tenth year reenrollment randomized trial investigating the effects of childhood probiotics and calcium supplementation on height and weight at adolescence.
Setiawan, EA, Rianda, D, Kadim, M, Meilianawati, Susanto, F, Kok, FJ, Shankar, AH, Agustina, R
Scientific reports. 2021;11(1):11860
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In combination, probiotics and calcium may help to support gut health and aid growth in early life. This 10 year follow up of 238 children from a previous randomised control trial aimed to determine the long-term effects of probiotic and calcium supplementation on growth during adolescence. The use of probiotics and calcium had no effect on changes in height, weight, or body mass for age. When more analyses were performed the use of Lactobacillus casei was shown to influence changes in body mass for age but only in females. Interestingly those in the probiotic group had poorer gut health than those who were not supplemented. It was concluded that in females, the use of probiotics and calcium during early life may decrease the risk of obesity later in life due to improved body mass. However, this warrants further research. This study could be used by health care professionals to understand that the use of probiotics and calcium in early life may have long-term benefits such as risk reduction of metabolic diseases.
Abstract
Microbiota and its modification with specific probiotics in early life could provide long term health benefits. Probiotics and calcium strengthen intestinal integrity and may support linear growth. This study investigated the long-term effects of childhood probiotics and calcium supplementation on growth in adolescence. We re-enrolled 238 adolescents aged 11-18 years from 494 children 10-years after 6-months of supplementation with either low-lactose milk fortified with low levels of calcium (LC, ∼50 mg/day, n = 53/124), with regular levels of calcium (RC, ∼440 mg/day, n = 70/126), or with regular calcium + 5 x 108 CFU/day Lactobacillus reuteri DSM 17938 (Reuteri, n = 55/124), or regular calcium + 5 x 108 CFU/day L. casei CRL 431 (Casei, n = 60/120). Changes in height-for-age z-score (HAZ) and body mass index-for-age z-score (BMIZ) were determined from the end of intervention to re-enrollment. General linear models were used to assess the effects on HAZ and BMIZ of group, gender, living area, maternal education, family income, physical activity, diet quality, nutritional status, and gut integrity as determined by urinary lactulose/mannitol ratio (L:M). Adolescent mean age was 15.3 years, mean HAZ was - 1.11, mean BMIZ was - 0.2 and median L:M (n = 155) was 0.23. Changes in HAZ and BMIZ were not significantly different between Casei, Reuteri, LC compared to RC. However, a significant decrease in BMIZ was observed among female adolescents in the Casei compared to RC group (- 0.5 SD, 95% CI - 0.8 to - 0.003, p = 0.048). Childhood probiotic and calcium supplementation may therefore selectively affect female adolescents.Clinical trial registration: This follow-up study has been registered at www.clinicaltrials.gov , Registry name: Rina Agustina, Registration number: NCT04046289, First Registration Date 06/08/19. web link: https://www.clinicaltrials.gov/ct2/show/NCT04046289 .
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Increased Colonic Permeability and Lifestyles as Contributing Factors to Obesity and Liver Steatosis.
Di Palo, DM, Garruti, G, Di Ciaula, A, Molina-Molina, E, Shanmugam, H, De Angelis, M, Portincasa, P
Nutrients. 2020;12(2)
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Intestinal permeability (IP) is dependent on the structure and function of the intestinal barrier. The gut barrier integrity is the result of ongoing equilibrium and crosstalk involving the microbiome, the mucus, the enterocytes [intestinal absorptive cells], the gut immune system, and the gut–vascular barrier. The main aim of this study was to explore the pan-enteric IP (stomach, small intestine, and colon) with respect to size and fat distribution, as well as the presence of liver steatosis. The study is a cohort study that examined 120 subjects (obese n = 45, overweight n=30, normal weight n = 45). Groups were gender-matched except for the prevalence of males in the overweight group. Results highlight the existence of an association between colonic (but not stomach and small intestinal) permeability, obesity, and liver steatosis. Findings show that: - liver steatosis was detected in 69 (57.5%) subjects, of which 36 (52%) were males. The prevalence of liver steatosis increased from 4% in normal weight subjects to 77%, and to 98% in overweight and obese subjects, respectively. - gastrointestinal permeability changed between age groups at every tract, whereas stomach and small intestine IP decreased with age. Furthermore, this finding also occurred in subjects aged over or equal to 65 years, with respect to colonic permeability. Authors conclude that further studies must evaluate the possibility of modulating colonic permeability to allow both primary prevention measures and new therapeutic strategies in metabolic and liver diseases.
Abstract
Intestinal permeability (IP) is essential in maintaining gut-metabolic functions in health. An unequivocal evaluation of IP, as marker of intestinal barrier integrity, however, is missing in health and in several diseases. We aimed to assess IP in the whole gastrointestinal tract according to body mass index (BMI) and liver steatosis. In 120 patients (61F:59M; mean age 45 ± SEM 1.2 years, range: 18-75), IP was distinctively studied by urine recovery of orally administered sucrose (SO, stomach), lactulose/mannitol ratio (LA/MA, small intestine), and sucralose (SA, colon). By triple quadrupole mass-spectrometry and high-performance liquid chromatography, we measured urinary recovery of saccharide probes. Subjects were stratified according to BMI as normal weight, overweight, and obesity, and answered questionnaires regarding dietary habits and adherence to the Mediterranean Diet. Liver steatosis was assessed by ultrasonography. IP at every gastrointestinal tract was similar in both sexes and decreased with age. Stomach and small intestinal permeability did not differ according to BMI. Colonic permeability increased with BMI, waist, neck, and hip circumferences and was significantly higher in obese than in lean subjects. As determined by logistic regression, the odds ratio (OR) of BMI increment was significantly higher in subjects in the highest tertile of sucralose excretion, also after adjusting for age and consumption of junk food. The presence of liver steatosis was associated with increased colonic permeability. Patients with lower score of adherence to Mediterranean diet had a higher score of 'junk food'. Intestinal permeability tended to increase in subjects with a lower adherence to Mediterranean diet. In conclusion, colonic (but not stomach and small intestinal) permeability seems to be linked to obesity and liver steatosis independently from dietary habits, age, and physical activity. The exact role of these last factors, however, requires specific studies focusing on intestinal permeability. Results should pave the way to both primary prevention measures and new therapeutic strategies in metabolic and liver diseases.
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Brain fogginess, gas and bloating: a link between SIBO, probiotics and metabolic acidosis.
Rao, SSC, Rehman, A, Yu, S, Andino, NM
Clinical and translational gastroenterology. 2018;9(6):162
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D-lactic acid is produced by intestinal bacteria and a rise in levels can lead to D-lactic acidosis, causing neurological changes such as slurred speech and gait disturbances. This is frequently observed in short bowel syndrome. This small, observational study aimed to determine if brain fogginess (mental confusion, impaired judgement, poor short-term memory and difficulty concentrating) and intestinal gas and bloating is associated with D-lactic acidosis and small intestinal bacterial overgrowth (SIBO). 38 patients presenting with gas and bloating in the absence of short bowel syndrome, and with or without brain fog were assessed. All patients with brain fog were consuming probiotics, with a higher proportion of them diagnosed with SIBO and D-lactic acidosis, when compared to the non-brain fog group. The researchers stopped probiotics in all patients and administered antibiotics, observing a significant reduction in brain fog and gastrointestinal symptoms. Whilst this is a small, observational study, nutrition practitioners may wish to assess the likelihood of SIBO and D-lactic acidosis before recommending probiotics, especially in the presence of brain fog.
Abstract
BACKGROUND D-lactic acidosis is characterized by brain fogginess (BF) and elevated D-lactate and occurs in short bowel syndrome. Whether it occurs in patients with an intact gut and unexplained gas and bloating is unknown. We aimed to determine if BF, gas and bloating is associated with D-lactic acidosis and small intestinal bacterial overgrowth (SIBO). METHODS Patients with gas, bloating, BF, intact gut, and negative endoscopic and radiological tests, and those without BF were evaluated. SIBO was assessed with glucose breath test (GBT) and duodenal aspiration/culture. Metabolic assessments included urinary D-lactic acid and blood L-lactic acid, and ammonia levels. Bowel symptoms, and gastrointestinal transit were assessed. RESULTS Thirty patients with BF and 8 without BF were evaluated. Abdominal bloating, pain, distension and gas were the most severe symptoms and their prevalence was similar between groups. In BF group, all consumed probiotics. SIBO was more prevalent in BF than non-BF group (68 vs. 28%, p = 0.05). D-lactic acidosis was more prevalent in BF compared to non-BF group (77 vs. 25%, p = 0.006). BF was reproduced in 20/30 (66%) patients. Gastrointestinal transit was slow in 10/30 (33%) patients with BF and 2/8 (25%) without. Other metabolic tests were unremarkable. After discontinuation of probiotics and a course of antibiotics, BF resolved and gastrointestinal symptoms improved significantly (p = 0.005) in 23/30 (77%). CONCLUSIONS We describe a syndrome of BF, gas and bloating, possibly related to probiotic use, SIBO, and D-lactic acidosis in a cohort without short bowel. Patients with BF exhibited higher prevalence of SIBO and D-lactic acidosis. Symptoms improved with antibiotics and stopping probiotics. Clinicians should recognize and treat this condition.
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Fecal Microbiome and Food Allergy in Pediatric Atopic Dermatitis: A Cross-Sectional Pilot Study.
Fieten, KB, Totté, JEE, Levin, E, Reyman, M, Meijer, Y, Knulst, A, Schuren, F, Pasmans, SGMA
International archives of allergy and immunology. 2018;175(1-2):77-84
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Atopic diseases, such as atopic dermatitis (AD), asthma and rhinitis, are on the increase worldwide. Exposure to microbes may be important in the development of an atopic disease. Specifically, reduced early-life exposure is thought to be a contributing factor because microbial colonisation of the intestines during infancy plays a crucial role in the maturation of the immune system. AD, also called eczema, is an inflammatory skin disease often seen in small children. Food allergies are common in children with AD, the most common allergens being eggs, cow’s milk, peanuts, soy and wheat. This cross-sectional observational pilot study with 82 young children with a diagnosis of AD set out to identify distinct microbial patterns in the children’s faecal microbiomes associated with a clinical diagnosis of food allergy. Stool and blood samples were collected for a microbiome analysis and IgE antibody measurement, respectively. 20 children had a confirmed food allergy (most commonly to cow’s milk and peanuts), while almost half of the children without a diagnosed food allergy were sensitised to common food allergens after a food challenge. The study identified a faecal microbial signature in children with AD that differentiates between the presence and absence of food allergy. Children with AD and food allergy had more Escherichia coli and Bifidobacterium pseudocatenulatum species and less Bifidobacterium breve, Faecalibacterium prausnitzii and Akkermansia muciniphila species than children without food allergy. The authors concluded that the study supports a hypothesis that the intestinal microbiome differs in children with AD, depending on whether they have a food allergy or not. They call for future studies to confirm these findings.
Abstract
BACKGROUND Exposure to microbes may be important in the development of atopic disease. Atopic diseases have been associated with specific characteristics of the intestinal microbiome. The link between intestinal microbiota and food allergy has rarely been studied, and the gold standard for diagnosing food allergy (double-blind placebo-controlled food challenge [DBPCFC]) has seldom been used. We aimed to distinguish fecal microbial signatures for food allergy in children with atopic dermatitis (AD). METHODS Pediatric patients with AD, with and without food allergy, were included in this cross-sectional observational pilot study. AD was diagnosed according to the UK Working Party criteria. Food allergy was defined as a positive DBPCFC or a convincing clinical history, in combination with sensitization to the relevant food allergen. Fecal samples were analyzed using 16S rRNA microbial analysis. Microbial signature species, discriminating between the presence and absence food allergy, were selected by elastic net regression. RESULTS Eighty-two children with AD (39 girls) with a median age of 2.5 years, and 20 of whom were diagnosed with food allergy, provided fecal samples. Food allergy to peanut and cow's milk was the most common. Six bacterial species from the fecal microbiome were identified, that, when combined, distinguished between children with and without food allergy: Bifidobacterium breve, Bifidobacterium pseudocatenulatum, Bifidobacterium adolescentis, Escherichia coli, Faecalibacterium prausnitzii, and Akkermansia muciniphila (AUC 0.83, sensitivity 0.77, specificity 0.80). CONCLUSIONS In this pilot study, we identified a microbial signature in children with AD that discriminates between the absence and presence of food allergy. Future studies are needed to confirm our findings.