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Jogurt – potencjalna strategia w nietolerancji laktozy: znaczenie dawki

Edyta Mądry
,
Beata Krasińska
,
Małgorzata Woźniewicz
,
Sławomira Drzymała-Czyż
,
Waldemar Bobkowski
,
Teresa Torlińska
,
Jarosław Walkowiak

Przegląd Gastroenterologiczny 2012; 7 (2): 81–86
Data publikacji online: 2012/05/22
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Introduction



The National Institute of Diabetes and Digestive and Kidney Diseases of the NIH (USA) states that about 4 billion people worldwide cannot digest lactose, the main disaccharide of milk, and thus may not be able to absorb a sufficient amount of calcium from dairy products [1]. This indicates that their small intestinal lactase (LCT [MIM 603202]) activity is only a small fraction of the infantile level, not allowing for unlimited digestion of lactose throughout the course of a lifetime. Incomplete digestion of lactose may result in lactose malabsorption (LM), a condition in which undigested lactose may reach the colon, causing symptoms of abdominal pain, bloating, flatulence, cramps, and diarrhea, forming a syndrome known as lactose intolerance (LI) [2].

Recently it has been shown that the genotype C/C of the LCT promoter gene is responsible for predisposition to adult-type hypolactasia (ATH) [3]. The ATH is an inherited autosomal recessive trait leading to decreased LCT activity in the intestinal mucosa after weaning and it is thought to be the most common cause of milk intolerance in children, adolescents and adults, and the most common enzyme deficiency in humans overall [4]. Eliminating dairy products from the diet or limiting their consumption is the strategy taken by many LI individuals to avoid the associated abdominal discomfort. However, such a diet usually contains less calcium and vitamin D than the recommended daily intake and may lead to poor health outcomes, particularly in relation to bone mineral density and the risk of fractures [5, 6]. It is known, however, that most LI subjects can tolerate some amount of lactose and that the lactose ingested in fermented dairy products is better tolerated than that in milk [7-9]. Moreover, the calcium content in yogurt is much higher than in milk (415 mg for plain, low-fat yogurt vs. 285 mg for semi-skimmed milk, respectively, in one cup) [10].



Aim



The objective of the present study was to determine the cut-off point of a lactose dose, administered as a single serving in the form of yogurt, that is tolerated by LI healthy young adults.



Material and methods



Ten highly motivated, clinically symptomatic, otherwise healthy young adults with LI were enrolled in the study. The investigated group consisted of 5 women and 5 men, all of Caucasian descent, aged 20-25 years (me­dian: 23.0 years), with body mass index (BMI) ranging from 19 kg/m2 to 25 kg/m2 (median: 22.0 kg/m2). All of the enrolled participants reported symptoms indicative of lactose intolerance prior to the study.

A predisposition to ATH was confirmed by mole­cular analysis; all subjects were homozygous C/C at locus 13910 (–13910 C/C) upstream of the LCT gene (NM_005915.4:c.1917+326C>T; rs4988235). For –13910 T>C polymorphism detection, the kit MutaGEL Lactase (Immundiagnostik AG, Bensheim, Germany) was used. The details of applied methodology have been described elsewhere [11].

Lactose malabsorption was confirmed in all study participants based on a hydrogen-methane breath test (BT) with a load of 25 γ of lactose, following an overnight fast. More specifically, subjects were instructed not to eat or drink for at least 12 h before the test and to avoid slowly digested foods, including beans and other legumes, brans or high-fiber cereals, on the day before the test. Participants were not allowed to smoke, sleep or exercise vigorously for at last 1 h before or at any time during the test. Breath samples were collected at baseline (fasting) and every 30 min within the 3 h after the ingestion of lactose. The samples were analyzed with QuinTron MicroLyser DP Plus (Quintron, USA). A positive BT was defined as a breath H2 level increase of at least 20 ppm over the lowest preceding value within the test period, or a breath CH4 level increase of at least 12 ppm over the baseline within the test period, or as a combined increase (H2 and CH4) of at least 15 ppm within the test period.

After selection of the study group, a BT was performed three times in each of the subjects (with intervals of at least 7 days) after a load of 400, 200, 100 ml of yogurt as a single serving given as a drink (lactose content 19.2 g, 9.6 g, 4.8 γ respectively). Breath samples were collected at baseline (fasting) and 30, 60, 90, 120, 150, 180, 210, 240, 270 and 300 min after lactose-containing product ingestion. The excretion of gases is expressed as the sum of hydrogen and doubled methane expiration.

Clinical symptoms were assessed within the 12 h after each product load using the questionnaire adopted for the project. The issues addressed were:

1) abdominal pain (0 – abdominal pain did not occur/1 – discomfort/2 – mild pain/3 – pain impeding normal functioning/4 – unbearable pain),

2) number of stools (0 – no stool/ 1, 2, 3… – corresponded to the number of stools),

3) stool consistency (0 – formed/1 – mushy or compressed/2 – loose/3 – liquid),

4) intestinal rumbling (0 – lack/1–- barely perceptible/2 – moderately severe/3 – very severe).

In addition, the BT area under the curve (AUC) was calculated assuming that it reflects semi-quantitatively the production of the total amount of intestinal gases over the 5-h period. All values are expressed as median (1st-3rd quartile).

Statistical analysis of the data was performed using the Kruskal-Wallis test with post-hoc comparisons.



Ethical consideration



The protocol of the investigation was approved by the Ethical Committee of the Poznan University of Medical Sciences, Poland (150/11). Written informed consent was obtained from all subjects.



Results



The comprehensive data of BT after loading with 400, 200 and 100 ml of yogurt are shown in Table I. Nine subjects exhaled exclusively hydrogen, while in one individual the excretion of methane was also found. There were no significant differences in the fasting breath hydrogen/methane levels between the three doses of product. They did appear after lactose loading, reaching a level of significance at 90 min into the test. Ingestion of 400 ml of yogurt brought about abnormal BT results in all examined individuals. Consumption of 200 ml of yogurt resulted in abnormal BT results in two of ten subjects, while a load of 100 ml caused a borderline rise (20 ppm) of hydrogen excretion in one subject. However, residual fermentation of lactose was observed for several hours in all subjects (median value of hydrogen and methane excretion in 240 min was 6.5 ppm)

The values of hydrogen/methane AUC for various yogurt doses differ significantly (p < 0.00001). AUC values for 400 ml of yogurt (186.5 ppm × h [143.5-195.5 ppm × h]) were significantly higher than for 200 ml (74.0 ppm × h [61.5-100.9 ppm × h]) and 100 ml (26 ppm × h [19.4-45.5]); (p < 0.029 and 0.00001, respectively). A tendency towards statistical difference between the loads of 100 and 200 ml of yogurt was observed (p < 0.098).

All examined subjects reported symptoms after the ingestion of 400 ml of yogurt. The severity of symptoms was significantly higher than that observed after a load of 200 ml. After consuming 100 ml of yogurt, none of the examined individuals reported abdominal discomfort or changes in stool consistency (Table II).



Discussion



In the present study, 3 doses of yogurt served without a meal after a fasting period as a single dose were compared. The obtained data suggest that LI subjects can tolerate 100 ml of yogurt (lactose content 4.8 g) without clinical symptoms. It seems that a dose of 200 ml of yogurt (lactose content 9.6 g) may also be tolerated with minor or no symptoms, while 400 ml (lactose content 19.2 g) brought about typical symptoms in all examined LI subjects, and also evoked abnormal BT results in all of them. Despite the fact that 200 ml of yogurt did not cause severe clinical symptoms, the BT results in two subjects were abnormal, with one subject having a borderline BT result (20 ppm), while in all other individuals the hydrogen/methane excretion was significantly higher than in healthy subjects. Ingestion of a dose of 100 ml of yogurt was associated with a borderline rise of H2 production exclusively in one individual. However, in all studied subjects, the production of hydrogen/methane was higher than typically observed in healthy subjects.

Current dietary recommendations suggest a daily consumption of 3 glasses (about 700 ml) of fat-free or low-fat milk or equivalent milk products, in order to secure an appropriate calcium intake [12]. That dose (equivalent to about 35 γ of lactose) makes it a recommendation that is impossible for LI individuals to follow. Discussion concerning determination of the maximum tolerated dose of lactose in LI persons is still ongoing. Most of the available data arise from the studies based on milk consumption and do not provide an unequivocal answer. The maximum tolerated single dose of lactose suggested by different researchers varies widely from 6 γ to 25 γ [13-15]. It has long been known that lactose tolerance depends on the type of product in which it is ingested and that the lactose in yogurt is better tolerated than that in milk [16]. However, there are no published surveys determining the cut-off point for the lactose dose tolerated by LI subjects administered in the form of yogurt.

The results of the present study, in which LI subjects were able to clinically tolerate up to 9.6 γ of lactose consumed in the form of yogurt, are consistent with the results of the Alm study [17]. On the other hand, in the present study, the dose of 19.8 γ brought about clinical symptoms. This is not concordant with the findings of Savaiano et al. [7], who documented that 500 ml of yogurt (lactose content 20 g) did not cause abdominal distress. A likely explanation may be related to the enrollment criteria; subjects who were classified in the study of Savaiano et al. [7] as “lactose-deficient” were probably LM rather than LI.

Recently introduced genetic testing of the LCT promoter gene is an available and useful method for detection of LM predisposition [3, 18, 19]. In association studies relating genetic polymorphism and eating behavior, decreased consumption of milk in adults with the C/C genotype compared to those with at least one T allele was consistently reported, suggesting that LM-predisposed individuals avoid milk, presumably to reduce dairy-induced abdominal distress [20, 21]. In order to secure an appropriate calcium and vitamin D intake these individuals are encouraged to consume dairy products, which seems to be justified from a nutritional point of view. However, it has not been proven that such an approach, which would demand a tolerance of mild to moderate abdominal discomfort along with the presence of fermentation gases and osmotic substances, is safe. Therefore, it also raises some doubts whether the clinical symptoms should be the sole determinant of the threshold of dairy product consumption by LM people, especially since it has been shown by Hammer et al. [22] that the subjective symptoms in LM individuals did not correlate with the amount of malabsorbed lactose or with the volume or the rate of gas accumulation per se. It is worth emphasizing that while lactose ingestion may not provoke clinical symptoms itself, it may, however, result in overproduction of gases as evaluated and documented by BT in the present study. It is assumed that the maximum tolerated lactose dose is the one that did not provoke clinical symptoms. Thus, the studies performed to date are based exclusively on a subjective evaluation of intestinal discomfort. Even though, as in the Hertzler et al. [23] and Martini et al. studies [8], the ingested dose of lactose resulted in abnormal hydrogen production documented by BT, the researchers did not refer to that when discussing their results. Bearing in mind that LM subjects do not necessarily manifest symptoms of LI, further surveys assessing the possible chronic effects of excessive intestinal fermentation should be considered. The consequences of chronic over-production of gases have not been studied so far, although it has been proven with the use of jejunoscopy that the mucosa of LI subjects became hyperemic and edematous after lactose exposure [24].

Fermentation is one of the most important functions of the colonic flora and results in the production of volatile fatty acids, lactic acid and gases (hydrogen, carbon dioxide and sometimes methane) [25]. It was shown that diet affects the condition of colonic mucosa predominantly through its effects on microbiota [26]. Disturbances in the bacterial flora and excessive bacterial metabolism may result in the production of cytotoxic substances which promote chronic inflammation or the production of mutagenic compounds. There is evidence that many colonic diseases (pseudomembranous colitis, inflammatory bowel disease, colon cancer) are determined by interactions between the diet and microbiota [26, 27] which can be substantially changed by the intensive fermentation occurring in LI subjects after dairy consumption. On the other hand, it was demonstrated that the administration of viable microbial strains in the form of fermented products can induce a decrease in the concentration of the fecal enzymes

(B-glucuronidase, azoreductase, nitroreductase) involved in colonic carcinogenesis [28, 29]. The net effect of yogurt (milk/dairy product) consumption by LI individuals certainly requires further study.

In conclusion, a subjective observation of clinical symptoms suggests that young adult LI subjects may tolerate up to 200 ml of yogurt served in one meal. However, when considering the objective assessment of lactose malabsorption by breath test, it seems that the dose served per meal definitely should not exceed 100 ml.



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