ANNA ZAWISTOWSKA-ROJEK1,2, TOMASZ ZARĘBA1, AGNIESZKA MRÓWKA1 and STEFAN TYSKI1,2
1Department of Antibiotics and Microbiology, National Medicines Institute, Warsaw, Poland
2Department of Pharmaceutical Microbiology, Medical University of Warsaw, Warsaw, Poland
*Corresponding author: A. Zawistowska-Rojek, Department of Antibiotics and Microbiology, National Medicines Institute, Warsaw, Poland; e-mail: a.zawistowska@nil.gov.pl.
Submitted 2 February 2015, revised 31 July 2015, accepted 11 August 2015
DOI: 10.5604/17331331.1197281
Abstract
The aim of this study was to perform the microbiological analysis of quality of 25 probiotic products, available on the Polish market. Analysis of bacterial viability in probiotic products showed that not all of these preparations possess a suitable number of bacteria. Moreover, some of the tested probiotic products contained bacterial strains other than those declared by the manufacturer. All tested strains recovered from probiotic products were found to be resistant to metronidazole and susceptible to nitrofurantoin. The susceptibility to other antibiotics was strain specific. Probiotic products should be subject to regular and thorough inspection by appropriate institutions.
Key words: antimicrobial resistance, dietary supplement, FSMP, medicinal product, probiotics
Probiotics can be defined as „live microorganisms which when administered in adequate amounts confer a health benefit on the host”, according to the Food and Agriculture Organization of the United Nations and World Health Organization definition (FAO/WHO, 2001). A probiotic preparation must contain a specified minimal number of bacterial cells – colony forming units (cfu) per dose. A daily intake of minimum 108 – 1010 cfu per day is required to show the beneficial health effects (Czinn and Blanchard, 2009; Sanders and Huis in`t Veld, 1999). These effects seem to be strain specific and dose dependent. A number of probiotic strains, particularly those belonging to species of lactic acid bacteria (LAB) group, are used to induce health benefits for a variety of conditions and diseases throughout the world (Czinn and Blanchard, 2009). Many of these effects have been scientifically supported (FAO/WHO, 2001). These include improving the condition of the intestinal tract (traveller’s diarrhoea, antibiotic-associated diarrhoea) (FAO/WHO, 2001; Holzapfel et al., 2001; Chapman et al., 2011) decreasing the prevalence of vaginal infections (FAO/WHO, 2001), increasing immune function (FAO/WHO, 2001), and decreasing cholesterol and lipid levels (Pereira et al., 2003).
There are many probiotic preparations in the Polish market that are distributed as medicinal products, dietary supplements or food for special medical purposes (FSMP). These products contain live bacteria – mostly Lactobacillus and Bifidobacterium – that supposedly produce a beneficial effect on human health. Probiotics on the market are sold in multiple forms such as capsules containing single or multiple strains, liquids or powders. A description on the label of a probiotic should include: genus, species and strain designation, minimum viable number of each probiotic cells at the end of the shelf-life, suggested serving that must deliver the effective dose related to the health claims, proper storage conditions, and corporate contact details for consumer information (FAO/WHO, 2002). In Poland, there is no national governmental agency responsible for the control of dietary supplements and FSMP products including probiotics, so the quality of these products may not comply with the information accompanying the probiotic product. Particularly important is the actual number of viable organisms present in the commercial product, which may be lower than the declared value that guarantees its beneficial properties (Czinn and Blanchard, 2009).
Although the use of lactic acid bacteria has a long history and has acquired Generally Recognised as Safe (GRAS) status, the safety of selected strains should be evaluated before use, not only for virulence factors and other potential disease-causing traits, but also for their capability of acquiring and disseminating resistance determinants. The transfer of antibiotic- resistance genes from LAB reservoir strains to bacteria in the resident microflora of human gastrointestinal tract, and hence to pathogenic bacteria, has not been fully documented. Lactobacilli display a wide range of types of antibiotic resistance naturally, but in most cases antibiotic resistance is not of the transmissible type. Although plasmid-linked antibiotic resistance is not very common among lactobacilli, it does occur and its influence on safety should be taken into consideration (Ashraf and Shah, 2011; Liu et al., 2009; Wiatrzyk et al., 2007).
The purpose of this study was to evaluate the quality of selected probiotic preparations, primarily the count of bacteria present in the different batches of several preparations, stored before distribution at temperatures recommended by the manufacturers. Additional aims included identification of the bacterial strains and designation of antimicrobial susceptibility.
A total of 16 dietary supplements, seven FSMP and two medicinal products, from two or three different batches, available on the market were tested for the viability of probiotic bacteria (Table I). Fifteen of the products were tested 3-4 times to monitor viability of bacterial strains during validity time. In the case of the 10 other products, one or two series were tested once or twice. Samples were stored at room temperature or in the refrigerator, according to the manufacturers’ recommendations.
Each tested preparation was suspended in peptone water (Buffered NaCl-Peptone Solutions, Heipha), diluted and plated onto De Man Rogosa and Sharpe Agar (MRS-Agar, Merck) for Lactobacillus and Transgalactio-Oligosaccharides (TOS) Propionate Agar (Merck) with MUP Selective Supplement (Merck) for Bifidobacterium. The plates were incubated for 48-72 h at 37°C with 5% CO2 for Lactobacillus and in anaerobic conditions (GENbag anaer, bioMérieux) for Bifidobacterium. The microbial count was expressed as cfu per one dose (Fig. 1)
The strains isolated from probiotic products were identified by two methods – (i) API 50 CHL (bioMérieux) and API 20 A (bioMérieux) biochemical tests, (ii) Matrix-Assisted Laser Desorption/Ionization – Time of Flight Mass Spectrometry (MALDI-TOF MS), analysis was performed by ALAB Laboratories, Warsaw.
Identification of lactic acid bacteria showed different results depending on the method applied (Table I). Biochemical test API 50 CHL did not properly identify Lactobacillus rhamnosus strains and often recognised this species as Lactobacillus paracasei. Moreover, API 20A test recognised Bifidobacterium only to genera. Therefore MALDI – TOF MS was used to confirm the biochemical identification. Not all results of identification confirmed the strain species declared by the manufacturers. For example dietary supplement (Biotyk) was declared to contain Lactobacillus casei but API 50 CHL identified this strain as Lactobacillus lactis, and MALDI-TOF as L. rhamnosus with good identification to genus and possible identification to species. Other case was identification of Lactobacillus reuteri with API 50 CHL from BioGaia and LaciBios Femina, while manufacturer declared Lactobacillus fermentum. However, this might be caused by a change in the nomenclature, L. reuteri, L. fermentum biotype II and L. fermentum subsp. reuteri are used sometimes as synonyms.
Several strains described on the label by manufacturers were not identified, e.g. Lactobacillus helveticus from Lacidofil or Lactobacillus gasseri and L. reuteri from dietary supplements (Asecurin, Iladian, Provag). In some products, the identified strains were different from those specified on the label. Dietary supplement Colon C contained L. rhamnosus, Lactobacillus plantarum and L. lactis lactis, while the manufacturer declared that preparation contains Lactobacillus acidophilus and Lactobacillus brevis. In Asecurin, we identified the Lactobacillus delbrueckii strain, not declared by the manufacturer. Analysis of the viability of probiotic strains (Fig. 1) showed that not all of the tested preparations contained a suitable number of lactic acid bacteria, as declared on the label. Analysis of three different batches of medicinal products – Lakcid and Lacidofil, showed a decrease in the bacteria number during the specified time interval. In the case of Lacidofil, an adequate number of living cells was maintained until the end of the validity period, while in the case of the Lakcid, cfu decrease was too far below the declared value, at the end of the validity time. A decrease in cfu values at the end of validity period was observed among all tested batches, reaching 32-78% of the declared value. Only four of the tested probiotic products (MultiTabs Immunokid, BioGaia, Colon C, Latopic), which were stored at room temperature, showed proper bacterial survival during the investigated time period. In all tested batches of these preparations, the numbers of living bacterial cells were above the minimum level declared by the manufacturers. Seven other probiotic products (Ido Form Kid, Dicoflor 30 Kid, LaciBios Femina, Acidolac, Linex Forte, Provag, Triflora) were characterised as having different levels of bacterial viability depending on the batch. In some product batches, at the date of expiry, the numbers of bacteria were above the level declared by the manufacturer – however, other batches were characterised by a large decrease in the amount of probiotic bacteria. All of these batches were kept at room temperature, except for LaciBios Femina and Provag, which were stored in a refrigerator, according to the manufacturers` recommendations.
Ten of the tested products showed a decrease in the bacteria count in all of the tested batches. In these products, which were stored in different conditions (room temperature or refrigerator), the number of live microbial cells was very low (< 10% of the declared value) at all expiry dates, which would probably result in low or no therapeutic properties. In the case of two preparations (Nutriplant and Dicoflor 60), the tested batches were stored at different temperatures (room temperature or refrigerator), depending on the storage temperature used at the time of purchase (manufacturers` recommendation below 20°C). Generally, batches of products stored in the refrigerator were characterised by better bacterial survival than preparations kept at room temperature.
Antibiotic susceptibility for 16 antibiotics was assayed using disc-diffusion method according to The European Committee on Antimicrobial Susceptibility Testing (EUCAST) recommendations (www.eucast.org). Plates, with Mueller-Hinton Agar, were incubated for 48 h at 37°C in anaerobic conditions (GENbag anaer, bioMérieux). The diameter of the bacterial growth inhibition zone was measured and interpreted according to Clinical and Laboratory Standards Institute (CLSI) Table II. Experiments were performed in duplicate.
All bacterial strains were resistant to metronidazole (lack on any growth inhibition zone) and sensitive to nitrofurantoin. Tested probiotic preparations were resistant to colistin and fusidic acid (except Biotyk). Most of the tested bacterial strains were also resistant to vancomycin (except strains from Linex Forte and Biotyk) and trimethoprim/sulfametoxazole (except strains from Linex Forte, Biotyk, Nutriplant, Lacium Zdrovit and Colon C). Bacterial strains from medicinal product Lacidofil – L. rhamnosus and L. helveticus, the only of tested strains, showed resistance to cefuroxime – II generation cephalosporin. Cefotaxime, a third-generation cephalosporin, inhibited the growth of most probiotic strains – only bacteria from Lacidofil and Dicoflor 60 preparations (L. rhamnosus GG) were resistant. CLSI guidelines for Staphylococcus and Enterococcus, in the case of ampicilin, are different, so it cannot be clearly defined which tested strains from the probiotic products were resistant or sensitive to this antibiotic. Basing on the CLSI guidelines for reference strains, it can be concluded that strains from probiotic products Lakcid (L. rhamnosus), Lactiv up (L. acidophilus) and Acidolac (L. acidophilus, Bifidobacterium BB-12) were resistant to ampicillin. In the case of clindamycin and erythromycin, only strains from preparations Lakcid, Colon C and Lacium Zdrovit (only to clindamycin) were resistant. Trimethoprim/sulfamethoxazole inhibited the growth of all L. plantarum strains contained in the probiotic products: Nutriplant, Lacium Zdrovit, Colon C and also the strains from Linex Forte and Biotyk.
Considering the significant increase in the annual consumption of probiotic products, it is very important that these products should be of proper quality, containing probiotic strains that are well documented regarding safety and functionality (Sanders and Huis in`t Veld, 1999). However, the analysis of the obtained microbiological results clearly shows that the quality of tested probiotic products is far from ideal.
Bacteria viability of probiotic medicinal products in the Polish market were previously analysed by Szajewska et al. (2002). From five tested products, four possessed the bacteria count in accordance with the manufacturer’s declaration. One product had a low number of probiotic bacteria. Szajewska et al. (2004) also investigated the quality of probiotic products licensed for medicinal purposes. Microbiological and genetic analysis showed that, in terms of quality, only three of five products contained the bacterial strains claimed on the label. Quantitative analysis demonstrated that 89% (57 of 64) of samples contained bacterial counts at the cell densities (doses) claimed on the label. Coeuret et al. (2004) performed some analyses of European probiotic products. In food supplements, the numbers of colonies were in accordance with data declared on the label – however, in the tested nutritional supplements, there were no viable lactobacilli found, even though the labels claimed that the product contained high numbers of various lactic acid bacteria. A recent study made by Temmerman et al. (2002) showed that numbers of viable bacteria were generally lower in food supplements than in dairy products, with no viable bacteria being found in 37% of food supplements. Moreover, 9 of 30 tested food supplements contained microorganism species other than those indicated on the product label. Research carried out by Hamilton-Miller et al. (1998) on 21 different kinds of supplements showed that only seven UK products completely fulfilled their label quantitative claims. Moreover, only 9 of 21 products contained exclusively the species stated on the label, with the other 12 products lacking one or more of the stated species. Sometimes the species have been incorrectly identified, or a contaminant strain was present. Only 7 of 21 products tested were both qualitatively and quantitatively bacteriologically satisfactory (Hamilton-Miller et al., 1998).
Table I
Detailed information on bacterial strains’ identification in analysed probiotic products.
| Product | Manufacturer | Preparation form | Medicinal product/ Dietary supplement/ Food for Special Medical Purpose (FSMP) | Number of analysed batches | Time to expire when observed significant decrease in the number of bacteria (months) | Declared microorganism presented | Biochemical identification (API 50 CHL/API 20A) | Identification MALDI-TOF MS |
| Lacidofil | Merck | Capsules | Medicinal product | 3 | Not observed | L. rhamnosus
L. helveticus (formerly L. acidophilus) |
L. rhamnosus | L. rhamnosus |
| Lakcid | Biomed | Powder | Medicinal product | 3 | Not observed | L. rhamnosus | L. rhamnosus | L. rhamnosus |
| Acidolac | Polpharma | Powder | FSMP | 3 | Not observed | L. acidophilus
Bifidobacterium BB-12 |
L. acidophilus
Bifidobacterium ssp.1 |
L. acidophilus
B. animalis ssp. lactis |
| Asecurin | Aflofarm | Capsules | Dietary supplement | 1 | 11 | L. gasseri
L. reuteri L. rhamnosus |
L. rhamnosus
L.para.paracasei L. debrueckii |
n.t. |
| BioGaia | Ewopharma | Tablets | FSMP | 3 | Not observed | L. reuteri Protectis | L. fermentum | L. reuteri |
| Biotyk | Lekam | Capsules | Dietary supplement | 3 | 21 | L. casei | L. lactis lactis/ L. brevis |
L. rhamnosus* |
| Coloflor | Oleofarm | Capsules | FSMP | 1 | 10 | L. acidophilus DDS-1
B. lactis VABLA-12 |
L. acidophilus
Bifidobacterium |
n.t. |
| Colon C | A-Z Medica | Granulat | Dietary supplement | 3 | Not observed | L. acidophilus,
L. brevis |
L. rhamnosus
L. plantarum L. lactis lactis |
L. rhamnosus
L. plantarum |
| Dicoflor 30 Kid | Vitis Pharma | Capsules | FSMP | 3 | Depends on batch – 6 (batch 1) | L. rhamnosus GG | L. para.paracasei | L. rhamnosus |
| Dicoflor 60 | Vitis Pharma | Capsules | FSMP | 3 | Not observed | L. rhamnosus GG | L. para.paracasei | L. rhamnosus |
| Ido-Form Kid | Ferrosan | Tablets | Dietary supplement | 2 | Not observed | L. rhamnosus GG
B. animalis ssp. lactis |
L. para.paracasei
Bifidobacterium ssp.1 |
L. rhamnosus |
| Iladian | Aflofarm | Capsules | Dietary supplement | 2 | 15 | L. rhamnosus
L. reuteri L. gasseri |
L. rhamnosus | n.t. |
| LaciBios Femina | Asa | Capsules | Dietary supplement | 3 | Not observed | L. rhamnosus GR-1
L. reuteri RC-14 |
L. rhamnosus
L. fermentum |
L. rhamnosus**
L. reuteri* |
| Lacidar | Tantus | Capsules | Dietary supplement | 2 | 20 | L. bulgaricus
L. rhamnosus L. acidophilus |
L. para.paracasei
L. rhamnosus |
n.t. |
| Lacidozone | Ozone Laboratories | Capsules | Dietary supplement | 1 | 7 | L. acidophilus
B. breve |
L. acidophilus | n.t. |
| Lacium Zdrovit | Zdrovit | Capsules | Dietary supplement | 3 | 17 | L. plantarum | L. plantarum | L. plantarum |
| Lactiv up | Farma-Projekt | Capsules | Dietary supplement | 3 | 9 | L. acidophilus | L. acidophilus | L. acidophilus |
| Lactoral | Biomed | Capsules | Dietary supplement | 1 | 8 | L. plantarum PL 02
L. rhamnosus KL 53A B. longum PL 03 |
L. rhamnosus
Bifidobacterium |
n.t. |
| Latopic | IBSS Biomed | Powder | FSMP | 3 | Not observed | L. paracasei ŁOCK 0919
L. casei ŁOCK 0900 L. casei ŁOCK 0908 |
L. rhamnosus
L. para. paracasei |
n.t. |
| Linex Forte | Lek Pharmaceuticals | Capsules | Dietary supplement | 3 | Not observed | L. acidophilus,
B. animalis ssp. lactis |
L. acidophilus
Bifidobacterium ssp. 1 |
L. acidophilus
B. animalis ssp. lactis |
| MultiTabs ImmunoKid | Ferrosan | Tablets | Dietary supplement | 3 | Not observed | L. rhamnosus GG | L. para.paracasei | L. rhamnosus |
| Nutriplant | Agropharm | Capsules | Dietary supplement | 3 | 3 (room temp.) | L. plantarum | L. plantarum | L. plantarum |
| Provag | Biomed | Capsules | FSMP | 2 | Not observed | L. gasseri 57C
L. fermentum 57A L. plantarum 57B |
L. fermentum
L. plantarum |
n.t. |
| Sanprobi IBS | Sanum Poland | Capsules | Dietary supplement | 3 | 13 | L. plantarum 299v | L. plantarum | n.t. |
| Triflora | Farmapia | Capsules | Dietary supplement | 2 | Depends on batch –
19 (batch 2) |
L. acidophilus
L. paracasei B. bifidum |
L. acidophilus
L. paracasei B. bifidum |
n.t. |
*Good identification to genus, possible identification to species, ** Possible identification to genus, n.t. – not tested
Table II
Susceptibility of microbial strains present in tested probiotic products to antimicrobial agents according to CLSI guidelines for Enterococcus spp. and Staphylococcus spp.
| Product/ antibiotic | Lakcid | Lacidofil | LaciBios Femina | Lactiv up | Acidolac | Linex Forte | IdoForm Kid | Biotyk | Nutriplant | Dicoflor 30 Kid | Dicoflor 60 | Lacium Zdrovit | BioGaia | MultiTabs ImmunoKid | Colon C | |
| Ampicillin AMP (10 µg) | R | S | S | R | R | S | S | S | S | S | S | S | S | S | S | |
| Cefaclor CEC (30 µg) | R | R | R | R | R | S | I | S | S | R | R | I | I | R | R | |
| Ciprofloxacin CIP (5 µg) | S | S | S | R | I | I | I | S | R | S | S | R | S | I | S | |
| Gentamycin GEN (10 µg) | S | S | S | S | S | R | R | S | S | S | S | S | I | S | S | |
| Colistin CST (10 µg)* | 10 | 6 | 12 | 6 | 6 | 6 | 6 | 21 | 12 | 6 | 6 | 6 | 6 | 6 | 6 | |
| Cefotaxime CTX (30 µg) | S | R | I | S | S | S | I | S | S | S | R | S | I | I | I | |
| Cefuroxime CXM (30 µg) | S | R | S | S | S | S | S | S | S | S | S | I | S | I | S | |
| Clindamycin CLI (2 µg) | R | S | S | S | S | S | I | S | I | S | I | R | I | S | R | |
| Doxycycline DOX (30 µg) | R | I | S | I | S | S | S | S | R | S | S | R | S | S | R | |
| Erythromycin ERY (15 µg) | R | S | S | S | S | S | S | S | S | S | S | S | S | S | R | |
| Nitrofurantoin NIT (300 µg) | S | S | S | S | S | S | S | S | S | S | S | S | S | S | S | |
| Fusidic acid FA (10 µg) | R | R | R | R | R | R | R | S | R | R | R | R | R | R | R | |
| Cefazolin CFZ (30 µg) | R | R | S | R | R | S | R | S | S | R | R | I | I | R | R | |
| Metronidazole MTZ (50 µg)* | 6 | 6 | 6 | 6 | 6 | 6 | 6 | 6 | 6 | 6 | 6 | 6 | 6 | 6 | 6 | |
| Trimethoprim/ sulfametoxazole SXT (1.25/23.75 µg) | R | R | R | R | R | S | R | S | S | R | R | S | R | R | S | |
| Vancomycin VAN (30 µg) | R | R | R | R | R | S | R | S | R | R | R | R | R | R | R |
*Lack in CLSI guidelines, presented diameter (mm) of growth inhibition zones. Resistant strains are shaded background. S – susceptible, I – intermediately susceptible, R – resistant
The profiles of antimicrobial susceptibility of LAB have been documented in many countries (Liu et al., 2009). Lactobacillus strains are usually susceptible to cell-wall-targeting penicillins, but are more resistant to cephalosporins. Many Lactobacillus species showed a high level of resistance to vancomycin. On the other hand, lactobacilli are generally susceptible to low concentrations of many inhibitors of protein synthesis, such as chloramphenicol, macrolides, lincosamides, and tetracyclines, but their resistance to aminoglycosides is often high (Gueimonde et al., 2013), which was not confirmed by our studies (only strains from product Linex Forte were resistant to gentamicin). Lactobacillus strains are naturally resistant to nalidixic acid, trimethoprim/sulfametoxazole and metronidazole (Hummel et al., 2007). Resistance of lactobacilli to metronidazole might be caused by the absence of hydrogenase activity (Danielsen and Wind, 2003). Moreover, L. rhamnosus strains are resistant to vancomycin, which distinguishes them from vancomycin-sensitive L. acidophilus (Wiatrzyk et al., 2007). Research carried out by Temmerman et al. (2002) on 187 strains isolated from probiotic products subjected to antibiotic susceptibility testing showed that 79% and 65% of these isolates were resistant to kanamycin and vancomycin, respectively. In our study, in 2 of 15 tested probiotic products, bacteria susceptible to vancomycin were observed. Wiatrzyk et al. (2013) confirmed that all tested L. rhamnosus were resistant to vancomycin. Moreover, this study demonstrated resistance of probiotic strains present in products Lakcid and Lakcid forte to: penicillin, ampicillin, amoxicillin, piperacillin, cefuroxime, cefotaxime, ceftazidime, cefepime, cefradine, cloxacillin, imipenem, meropenem, gentamicin, neomycin, netilmicin, tobramycin, streptomycin, erythromycin, vancomycin, teicoplanin, doxycycline, trimethoprim/sulfamethoxazole, nalidixic acid, metronidazole, clindamycin and colistin. Investigations conducted in our laboratory have not confirmed resistance of bacterial strains from Lakcid to ampicillin, cefotaxime, cefuroxime and gentamicin. In the case of colistin, there are no guidelines from the CLSI for the interpretation of bacterial sensitivity. Moreover, sensitivity to nitrofurantoin was observed. Strains from products Lacidofil and EcoVag tested by Wiatrzyk et al. (2013) were resistant to aminoglycosides, glycopeptides and clindamycin, colistin and chemotherapeutics (trimethoprim/sulfamethoxazole, metronidazole, nalidixic acid). These results are also not entirely consistent with ours, where probiotic strains from Lacidofil were sensitive to gentamicin and clindamycin, and as above there were no CLSI guidelines for colistin. Wiatrzyk et al. (2013) used European Food Safety Authority (EFSA) guidelines for the interpretation of their results. Moreover, comparison of the antimicrobial susceptibility of L. rhamnosus PEN to gentamycin was assayed by two methods, disc diffusion and the E-test, which showed different results. In the disc-diffusion method, the L. rhamnosus PEN strain was susceptible to gentamycin, but when using the E-test, this strain was resistant. Similarly, contradictory results were obtained in the case of L. delbrueckii subsp. bulgaricus strain. Nawaz et al. (2011) also observed resistance of lactic acid bacteria to nalidixic acid, vancomycin and kanamycin, while susceptibility of all tested strains to ampicillin was noted. In our study, bacteria in 3 of 15 tested probiotic products showed resistance to ampicillin.
Many probiotic products from the Polish market (medicinal products, dietary supplements and food for special medical purposes) contain too few probiotic bacteria cells, which probably cause low or even no beneficial effect on health. In addition some of the tested probiotic products contained different bacterial strains than those declared by the manufacturer. Taking into account the fact that each strain is characterised by different properties, such situations should not occur. Each strain has a different antibiotic resistance profile, and incorrect labelling of strains will also results in no beneficial effect on health. Only one medicinal product, two dietary supplements and two FSMP of all tested 25 different products showed a good quality with respect to the number of bacterial cells. In 15 of 25 tested products, compliance of species with the label was proved. Products with inappropriate number of bacterial cells or with not confirmed properties, which may even cause serious health problems, should be withdrawn from the market. On the basis of the obtained results, it can be concluded that all probiotic products available on the market should be subjected to routine and thorough inspection by appropriate institutions.
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