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A high molecular weight soluble fraction of tempeh protects against fluid losses in Escherichia coli-infected piglet small intestine

Published online by Cambridge University Press:  01 August 2007

Jeroen L. Kiers
Affiliation:
Laboratory of Food Microbiology, Agrotechnology and Food Sciences Group of Wageningen UR, PO Box 8129, 6700 EV Wageningen, The Netherlands Animal Sciences Group of Wageningen UR, Animal Resources Development, PO Box 65, 8200 AB Lelystad, The Netherlands
M. J. Rob Nout
Affiliation:
Laboratory of Food Microbiology, Agrotechnology and Food Sciences Group of Wageningen UR, PO Box 8129, 6700 EV Wageningen, The Netherlands
Frans M Rombouts
Affiliation:
Laboratory of Food Microbiology, Agrotechnology and Food Sciences Group of Wageningen UR, PO Box 8129, 6700 EV Wageningen, The Netherlands
Marius J. A. Nabuurs
Affiliation:
Animal Sciences Group of Wageningen UR, Animal Resources Development, PO Box 65, 8200 AB Lelystad, The Netherlands
Jan van der Meulen*
Affiliation:
Animal Sciences Group of Wageningen UR, Animal Resources Development, PO Box 65, 8200 AB Lelystad, The Netherlands
*
*Corresponding author: Dr Jan van der Meulen, fax +31 320 238050, email [email protected]
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Abstract

Enterotoxigenic Escherichia coli (ETEC) is an important cause of diarrhoea in children and piglets. Infection of ETEC results in fluid secretion and electrolyte losses in the small intestine. In this study the effects of tempeh, a traditional fungal fermented soyabean product, on fluid losses induced by ETEC infection in piglets was investigated. Pairs of ETEC-infected and non-infected small intestinal segments of piglets were perfused simultaneously for 8 h with pre-digested tempeh, its supernatant and saline as an internal control. In saline perfused segments, ETEC infection reduced net fluid absorption by more than 500 μl/cm2, whereas this reduction was significantly less for pre-digested tempeh and its supernatant (75 and 282 μl/cm2, respectively). The supernatant of pre-digested tempeh was also compared with its permeate and retentate fractions. These fractions were created by ultra-filtration and contained respectively low and high molecular weight (>5 kDa) compounds. Again ETEC infection caused a significant reduction of net fluid absorption when perfused with saline (386 μl/cm2) and also with the permeate fraction (300 μl/cm2), but much less with the supernatant and the retentate fraction (125 and 140 μl/cm2, respectively). The reduction in net fluid absorption upon ETEC infection when perfused with supernatant of either undigested or pre-digested tempeh was not different. Therefore from this study it can be concluded that a high molecular weight soluble fraction of tempeh is able to protect against fluid losses induced by ETEC, suggesting that this could play a potential role in controlling ETEC-induced diarrhoea.

Type
Full Papers
Copyright
Copyright © The Authors 2007

One of the major pathogenic bacteria associated with acute diarrhoea is enterotoxigenic Escherichia coli (ETEC)Reference Hampson and Gyles1, Reference Bhan2. Diarrhoea caused by ETEC is a persisting health problem in children and young animalsReference Bhan2Reference Nagy and Fekete4. Treatment options for acute gastroenteritis mainly rely on oral rehydration solution, although the volume, frequency or duration of diarrhoea are not reduced using conventional oral rehydration solutionReference Bhan2, Reference Mahalanabis5.

Tempeh is a traditional fermented food made from soaked dehulled and cooked whole soyabeans inoculated with a mould, usually of the genus Rhizopus Reference Nout and Kiers6. An important function of the mould in the fermentation process is the synthesis of biomass and enzymes that hydrolyse soyabean constituents and contribute to the development of a desirable texture, flavour and aroma of the product. The process also inactivates or eliminates certain anti-nutritional factors and the enzymatic degradation improves the nutritional qualityReference Nout and Kiers6.

Tempeh has been reported to contain an antibacterial substanceReference Wang, Ruttle and Hesseltine7Reference Kobayasi, Okazaki and Koseki9 and in vitro tempeh extracts are able to inhibit adhesion of ETEC to piglet small intestinal brush border membranesReference Kiers, Nout, Rombouts, Nabuurs and van der Meulen10. Rabbits infected with ETEC and fed tempeh showed reduced diarrhoea compared with rabbits fed diets without tempehReference Karmini, Affandi, Hermana, Sudarmadji, Suparmo and Raharjo11. Perfusion of small intestinal segments of piglets with pre-digested tempeh strongly reduced ETEC-induced intestinal fluid lossesReference Kiers, Nout, Rombouts, van Andel, Nabuur and van der Meulen12 and in ETEC-challenged weaned piglets the severity of diarrhoea was reduced by a diet containing tempeh compared with a control diet containing toasted soyabeansReference Kiers, Meijer, Nout, Rombouts, Nabuurs and van der Meulen13. In malnourished children tempeh was reported to be beneficial in terms of duration of diarrhoea episodes and rehabilitation period when supplemented to their dietReference Kalavi, Muroki, Omwega and Mwadime14Reference Karyadi and Lukito16.

The present study was undertaken to investigate whether the reduction of ETEC-induced intestinal fluid loss in piglets by tempeh can be attributed to unsoluble or to water-soluble tempeh fractions of either low or high molecular mass.

Material and methods

Tempeh

Dehulled yellow-seeded soyabeans (Glycine max) were soaked overnight for about 16 h in tap-water while undergoing accelerated lactic acid fermentation using naturally acidified soaking water as an inoculumReference Nout, de Dreu, Zuurbier and Bonants van Laarhoven17. Subsequently, the beans were washed with tap-water and cooked (100°C) in fresh tap-water at a ratio of 1:3 for 20 min, and cooled to room temperature within 20 min by evaporation of adhering water by spreading them on perforated trays. Sporangiospore suspension was obtained by scraping off the sporangia from pure slant cultures of Rhizopus microsporus var. microsporus LU 573 grown on malt extract agar (Oxoid, CM 59) for 7 d at 30°C and suspending them in sterile distilled water with 0·85 % NaCl and 0·1 % peptone. After inoculation of the cooked soyabeans with the sporangiospore suspension (1 %, v/w), the beans (450 g) were packed in hard-PVC, perforated boxes (205 × 90 × 45 mm) and incubated at 30°C for 72 h. The resulting fresh tempeh was cut into 1 cm dice and dehydrated for 6 h at 60°C, ground using a 1·0 mm screen and stored at − 20°C until use.

Tempeh was pre-digested as described earlierReference Kiers, Nout and Rombouts18. It was suspended in distilled water (5 g/30 ml) and incubated while stirring with 2 ml α-amylase solution consisting of 125 000 units/l α-amylase (A-1031; Sigma Chemical Co., St Louis, MO, USA), 1·5 g/l NaCl, 1·5 g/l K2HPO4, 0·5 g/l Na2CO3 (pH 7·0) for 30 min at 37°C. Next, the pH was adjusted to 4·0 using 5 m-HCl and the suspensions were incubated with 8 ml stomach-medium (0·1 g/l lipase (Rhizopus F-AP15; Amano Pharmaceuticals, Nagoyy, Japan), 0·125 g/l pepsin (P-6887; Sigma), 3·1 g/l NaCl, 1·1 g/l KCl, 0·6 g/l Na2CO3, 0·11 g/l CaCl2, pH 4·0) for 1 h at 37°C. The pH was then adjusted to 6·0 using solid NaHCO3. Finally, 10 ml of a 2 % pancreatic solution (20·0 g/l pancreatin (P-1750; Sigma), 5·0 g/l bile (B-3883; Sigma), 5·0 g/l NaCl, 0·68 g/l KH2PO4, 0·3 g/l Na2HPO4, 0·84 g/l NaHCO3) was added and the suspensions were incubated for 30 min at 37°C. After pre-digestion the slurry was diluted using distilled water to 6·5 % DM.

Part of the suspension was centrifuged at 3000 g for 15 min at 4°C. The supernatant was filtered through a filter aid (Celite®545, 22 140; Fluka, Buchs, Switzerland) to remove residual coarse particles and finally filtered through a 0·22 μm filter (Steritop SCGPT05RE; Millipore, Billerica, MA, USA).

Supernatant of pre-digested tempeh was fractionated into permeate and retentate using ultra-filtration through a spiral wound membrane with molecular weight cut-off of 5 kDa (S2K328; Koch, Wilmington, MA, USA) against distilled water. In order to obtain fractions having the same volume as that of the original supernatant, permeate and retentate volumes were adjusted using rotary vacuum evaporation at 40°C.

Analysis

DM content of pre-digested supernatant, permeate and retentate was determined by drying aliquots until constant weight and nitrogen content was measured using a NA2100 nitrogen analyser (Interscience, Breda, The Netherlands). After centrifugation (10 min, 1300 g), sodium, potassium and chloride concentrations were determined using an Electrolyte 4+ analyser (Nova Biomedical, Waltham, MA, USA) and osmolality was determined using a cryoscopic osmometer (Osmomat; Gonotec, Berlin, Germany).

Gel permeation chromatography was performed on a LC-10Ai HPLC (Shimadzu Benelux, 's-Hertogenbosch, The Netherlands) equipped with a Superdex Peptide column (17-5003-01; Pharmacia Biotech, Piscataway, NJ, USA) and elution at 30°C with 0·1 % (v/v) trifluoroacetic acid and 30 % (v/v) acetonitrile at 0·5 ml/min. The eluate was monitored using a UV detector at 200 nm. Calibration was performed using proteins and peptides ranging from 200 to 7000 Da.

High-performance size-exclusion chromatography was performed on a SP8800 HPLC (Spectra Physics, Mountain View, CA, USA) equipped with three columns (each 300 × 75 mm) of Bio-Gel TSK in series (40XL, 30XL and 20XL; Bio-Rad Labs, Hercules, CA, USA) in combination with a TSK guard column (40 × 6 mm) and elution at 30°C with 0·2 m-NaNO3 at 0·8 ml/min. The eluate was monitored using a refractive index detector. Calibration was performed using dextrans ranging from 180 Da to 500 kDa.

Net intestinal absorption

All procedures involving animal handling and testing were reviewed and approved by the Animal Care and Ethics Committee of the Animal Sciences Group Lelystad, The Netherlands.

Piglets (crossbred Yorkshire × (Large White × Landrace)) were weaned at 3 weeks of age. About 2 weeks after weaning biopsies from the duodenal mucosa were taken using a fiberscope (Olympus GIF XP10; Olympus, Hamburg, Germany) and receptor status was determinedReference Sellwood, Gibbons, Jones and Rutter19. Sixteen piglets that expressed the receptor (K88/F4) involved in binding of the ETEC strain were used in the experiments 3 weeks after weaning.

The small intestinal segment perfusion test was carried out essentially as described beforeReference Nabuur, Hoogendoorn, van Zijderveld and van der Klis20. Up to ten segments, with a cranial inflow and a caudal outflow tube and 20 cm long, were situated between 35 and 65 % of the total length of the small intestine.

At 15 min before the perfusion started, the odd-numbered segments were injected with 5 ml ETEC (5 × 109 colony forming units, O149:K91:K88ac, producing LT and STb) and the even-numbered segments with 5 ml PBS. In each piglet, pairs of segments (a non-infected and an adjacent ETEC-infected) were perfused with either saline (supplemented with 0·1 % glucose and 0·1 % casamino acids and serving as an internal control to determine the maximum response to the infection) or any of the tempeh products, using a Latin-square design. Each segment was perfused with 64 ml product over 8 h, by injecting 2 ml product every 15 min.

Three consecutive experiments were carried out. In experiment 1 the total pre-digested tempeh, its supernatant, saline (and another not relevant soyabean product) were tested in four piglets in a 4 × 4 Latin-square design. In experiment 2 saline, the supernatant of the pre-digested tempeh, the permeate and the retentate obtained after ultra-filtration were tested in eight piglets in a replicated 4 × 4 Latin-square design. In experiment 3 with four piglets saline, the supernatant of pre-digested tempeh, the supernatant of undigested tempeh (and another not relevant soyabean product) were tested in a 4 × 4 Latin-square design.

At the end of the small intestinal segment perfusion test the product remaining in the segments was blown out into the drainage bottles. The piglets were killed by injection of sodium pentobarbital (200 mg/kg body weight) and the segments were cut from the mesenterium and their length was measured.

Net fluid, sodium, chloride and solute absorption were calculated from the difference between the volume and concentration of inflow and outflow divided by the surface area (length × circumference) of each segment. Reduction in net fluid absorption upon ETEC infection was determined by subtracting net fluid absorption in ETEC-infected segments from net fluid absorption in non-infected segments perfused with the same perfusion fluid.

Statistics

Results of non-infected and ETEC-infected segments perfused with the same product were compared using the Student's paired t test. The effect of the perfusion fluid on net fluid absorption upon ETEC infection was analysed with ANOVA for a Latin-square design with piglet, pair of segment and treatment as model effects. Results on net fluid absorption and osmolality in experiment 2 were analysed using linear regression analysis. All statistics were performed with GraphPad Prism version 4.00 for Windows (GraphPad Software, San Diego, CA, USA). Net absorption of fluid, DM, sodium, chloride and solutes are presented as means and their standard errors.

Results

Pre-digested tempeh and its supernatant

In experiment 1 ETEC infection in saline-perfused segments resulted in a decrease in net fluid absorption of more than 500 μl/cm2 compared with non-infected segments (Fig. 1). The reduction in net fluid absorption upon ETEC infection was significantly less when segments were perfused either with pre-digested tempeh or its supernatant. The difference in reduction in net fluid absorption upon ETEC infection between pre-digested tempeh (75 μl/cm2; 14 % compared with saline) and its supernatant (282 μl/cm2; 53 % compared with saline) was substantial but not significantly different.

Fig. 1 Fluid loss upon enterotoxigenic Escherichia coli (ETEC) infection after perfusion with saline, pre-digested tempeh and its supernatant. Values are means with their standard errors depicted by vertical bars. a,b Mean values with unlike superscript letters were significantly different (P < 0·05).

Tempeh supernatant, permeate and retentate

Ultra-filtration of the supernatant of pre-digested tempeh resulted in a permeate fraction containing only low molecular weight compounds and a retentate fraction containing all compounds >5 kDa and some residual low molecular weight compounds (Fig. 2). Similar chromatograms were observed for gel permeation chromatography protein/peptide analysis and areas under the curve showed that around 50 % of the total DM in supernatant of pre-digested tempeh consisted of proteinaceous or protein-derived compounds (nitrogen × 6·25) (Table 1). After ultra-filtration, the permeate contained the majority (approximately 65 %) of the initial nitrogen. The osmolality of the retentate was the lowest and about a third of the permeate and a fourth of the supernatant.

Fig. 2 High-performance size-exclusion chromatography elution patterns of supernatant of pre-digested tempeh (●) and the permeate (□) and retentate (○) fraction obtained after ultra-filtration. ↓ , Molecular weights of dextran standards.

Table 1 DM, nitrogen, sodium and chloride content and osmolality of the pre-digested supernatant and the permeate and retentate fractions obtained after ultra-filtration (Mean values with their standard errors)

In experiment 2 there was an inverse linear relationship between osmolality of the perfused fluids and net fluid absorption in non-infected segments (Fig. 3), with the net fluid absorption of retentate being the highest. Upon ETEC infection a significant decrease in net fluid absorption was observed for saline and the permeate (386 (sem 69) and 300 (sem 62) μl/cm2, respectively). The decrease in net fluid absorption upon ETEC infection and perfusion with either supernatant or retentate was not significant, being 125 (sem 37) and 140 (sem 42) μl/cm2, respectively. ETEC infection resulted in a decrease in net sodium and chloride absorption (Table 2). The reduction in sodium and chloride absorption was highest when perfused with saline and permeate and less when perfused with supernatant and retentate.

Fig. 3 Net fluid absorption in non-infected (□) and enterotoxigenic Escherichia coli-infected (■) segments perfused with saline and tempeh supernatant, permeate and retentate. Values are means with their standard errors depicted by bars. There was an inverse linear relationship between osmolality and net fluid absorption for non-infected segments (net fluid absorption = 1091 − 1·45 × osmolality; r 2 0·87).

Table 2 Average net absorption of sodium, chloride and solutes after perfusion with saline and tempeh supernatant, permeate and retentate (Mean values with their standard errors)

ETEC, enterotoxigenic Escherichia coli.

a–d Mean values within a column with unlike superscript letters were significantly different (P < 0·05).

Mean values were significantly different from those of the non-infected group: *P < 0·01; **P < 0·001.

Pre-digested and undigested tempeh supernatant

Pre-digestion of tempeh did not result in liberation of soluble carbohydrate polymers >8·5 kDa, whereas numerous low molecular weight compounds were formed (Fig. 4). Pre-digestion resulted in a marked increase in nitrogen levels (in low molecular weight compounds) and osmolality (Table 3).

Fig. 4 High-performance size-exclusion chromatography elution pattern of the supernatant of undigested (●) and pre-digested tempeh (○). ↓ , Molecular weight of dextran standards.

Table 3 Nitrogen content and osmolality of undigested and pre-digested supernatant of tempeh (Mean values with their standard errors)

The difference in net fluid absorption between non-infected and ETEC-infected segments in experiment 3 amounted to almost 400 μl/cm2 for perfusion with saline. Reduction in net fluid absorption upon ETEC infection was not different for undigested and for pre-digested tempeh supernatant (211 (sem 72) and 214 (sem 83) μl/cm2, respectively) and represented a reduction of 54 % compared with saline.

Discussion

Previously we demonstrated that pre-digested tempeh stimulates DM absorption and reduces ETEC-induced fluid and electrolyte losses in piglet small intestinal segments, whereas this was not the case for non-fermented soyabeansReference Kiers, Nout, Rombouts, van Andel, Nabuur and van der Meulen12. The protective effect of pre-digested tempeh against ETEC-induced fluid loss appears to be determined in part by the presence of the insoluble matrix of tempeh. The presence of insoluble material could probably modify fluid absorption as has been suggested for viscosity-enhancing agentsReference Go, Harper, Sia, Teichberg and Wapnir21, Reference Wapnir, Wingertzahn and Teichberg22. Whereas pre-digested tempeh as such reduced loss in net fluid absorption by about 85 % compared to saline, the supernatant of pre-digested tempeh reduced loss in net fluid absorption by about 50 %.

Although low osmolality promotes net fluid absorption in both non-infected and secreting intestineReference Kiers, Hoogendoorn, Nout, Rombouts, Nabuur and van der Meulen23Reference Thillainayagam, Hunt and Farthing25, the difference between net fluid absorption in non-infected and ETEC-infected segments is fairly independent of osmolalityReference Kiers, Hoogendoorn, Nout, Rombouts, Nabuur and van der Meulen23. Therefore the lower decrease in net fluid absorption upon ETEC infection for perfusion with supernatant and retentate cannot be attributed to osmolality and we hypothesize that tempeh components interfere in the pathogenesis of the ETEC infection, resulting either in reduction of secretion or stimulation of absorption, or both.

The mechanisms whereby high molecular weight soluble tempeh compounds exert their beneficial effects in the case of the observed reduced fluid and electrolyte losses remain to be determined. These may involve aspects of enzyme activity, interference with pathogenicity factors and stimulation of fluid absorption.

Tempeh contains a diversity of microbial enzyme activities. α-Galactosidase and protease activity were found in the supernatant of pre-digested tempeh and in its retentate but not in its permeate (JL Kiers, unpublished results). Enzymatic activity in the gut could degrade intestinal receptors for ETEC as was shown before for bromelainReference Chandler and Mynott26Reference Mynott, Guandalini, Raimondi and Fasano28. Components in the tempeh extract could also interfere with the (binding of) enteroxin, as was shown elsewhere for certain toxin receptor analoguesReference Takeda, Yoshino, Adachi, Sato and Yamagata29 or interfere in the cascade of events leading to an increased chloride secretion and inhibited sodium chloride absorption, as was shown for polyphenolic compounds in plant extracts and boiled riceReference Greenwood-van Meerveld, Tyler, Kuge and Ogata30Reference Mathews, MacLeod, Zheng, Hanrahan, Bennett and Hamilton32.

Tempeh components could also exert a pro-absorptive activity. This could be mediated through stimulated sodium–solute co-transport which is the basis for traditional oral rehydration therapyReference Farthing24. In the present study there was a net absorption of solutes both in the tempeh supernatant as well as in the permeate and retentate. Probably this reflected the absorption of low molecular weight components such as monosaccharides and amino acids present in supernatant and permeate and in low concentrations in retentate. Since the reduction of fluid loss was found only in the retentate but not in the permeate, which contained higher levels of compounds supposed to enhance fluid absorption through sodium–solute co-transport, coupled sodium–solute absorption is unlikely to be responsible for the observed protective effect.

Vegetable polysaccharides, like starchReference Wapnir, Wingertzahn, Moyse and Teichberg33, Reference Wingertzahn, Teichberg and Wapnir34 and gum ArabicReference Turvill, Wapnir, Wingertzahn, Teichberg and Farthing35Reference Wapnir, Teichberg, Go, Wingertzahn and Harper37, have been shown to enhance intestinal electrolyte and/or fluid absorption in normal and secreting rat small intestine. Gum Arabic has been shown to enhance net sodium absorption without altering net fluid absorption in normal rat jejunumReference Wapnir, Teichberg, Go, Wingertzahn and Harper37, whereas fluid absorption was increased in the case of diarrhoeaReference Turvill, Wapnir, Wingertzahn, Teichberg and Farthing35, Reference Wapnir, Wingertzahn, Moyse and Teichberg36. Enhanced absorption could be the result of increased accessibility of electrolytes and associated fluid to the microvillus membrane through the emulsifying properties of gum ArabicReference Wapnir, Wingertzahn, Moyse and Teichberg36, but also other physicochemical properties could play a roleReference Wapnir, Wingertzahn, Moyse and Teichberg33. Evidence for the possible involvement of tempeh polysaccharides in the protective effect described in the present study could be the presence of high molecular weight polysaccharides in the tempeh supernatant and its retentate. Additionally, the high-performance size-exclusion chromatography analysis of the supernatant of pre-digested tempeh was identical to the supernatant of undigested tempeh, especially with regard to high molecular weight compounds, and supernatant of undigested tempeh showed equal protection against ETEC-induced fluid loss as supernatant of pre-digested tempeh.

The present results warrant the protective role that tempeh could play in ETEC-associated diarrhoea and show the role of its high molecular weight soluble fraction. Further research is required to identify the component(s) in the high molecular weight soluble fraction which is responsible for the protective effect and to evaluate the specific mechanism(s) underlying the improved net fluid balance.

Acknowledgements

The authors thank Mirjana Eimermann, Gerrit de Vrij, Wendy Verwillegen (Numico Research BV, Wageningen), Gert-Jan de Graaf, Esther van Andel, Arie Hoogendoorn and Ank van Zijderveld-van Bemmel (Animal Sciences Group, Lelystad) for their excellent technical assistance. Financial support by the Dutch Ministry of Agriculture, Nature and Food Quality, as well as by Numico Research BV, Wageningen, The Netherlands is gratefully acknowledged.

References

Hampson, DJ (1994) Postweaning Escherichia coli diarrhoea in pigs. In Escherichia coli in Domestic Animals and Humans, pp. 171191 [Gyles, CJ, editor]. Wallingford, UK: CAB International.Google Scholar
Bhan, MK (2000) Current and future management of childhood diarrhoea. Int J Antimicrob Agents 14, 7173.CrossRefGoogle ScholarPubMed
Gaastra, W & Svennerholm, AM (1996) Colonization factors of human enterotoxigenic Escherichia coli (ETEC). Trends Microbiol 4, 444452.CrossRefGoogle ScholarPubMed
Nagy, B & Fekete, PZ (2005) Enterotoxigenic Escherichia coli in veterinary medicine. Int J Med Microbiol 295, 443454.CrossRefGoogle ScholarPubMed
Mahalanabis, D (1996) Current status of oral rehydration as a strategy for the control of diarrhoeal diseases. Indian J Med Res 104, 115124.Google ScholarPubMed
Nout, MJR & Kiers, JL (2005) Tempe fermentation, innovation and functionality: update into the third millennium. J Appl Microbiol 98, 789805.CrossRefGoogle Scholar
Wang, HL, Ruttle, DI & Hesseltine, CW (1969) Antibacterial compound from a soybean product fermented by Rhizopus oligosporus. Proc Soc Exp Biol Med 131, 579583.CrossRefGoogle ScholarPubMed
Wang, HL, Ellis, JJ & Hesseltine, CW (1972) Antibacterial activity produced by molds commonly used in oriental food fermentations. Mycologia 64, 218221.CrossRefGoogle ScholarPubMed
Kobayasi, S, Okazaki, N & Koseki, T (1992) Purification and characterization of an antibiotic substance produced from Rhizopus oligosporus IFO 8631. Biosci Biotechnol Biochem 56, 9498.CrossRefGoogle ScholarPubMed
Kiers, JL, Nout, MJR, Rombouts, FM, Nabuurs, MJA & van der Meulen, J (2002) Inhibition of adhesion of enterotoxigenic Escherichia coli K88 by soya bean tempe. Lett Appl Microbiol 35, 311315.CrossRefGoogle ScholarPubMed
Karmini, M, Affandi, E & Hermana, H (1997) The inhibitory effect of tempe on Escherichia coli infection. In International Tempe Symposium, pp. 157162 [Sudarmadji, S, Suparmo, S and Raharjo, S, editors]. Jakarta: Indonesian Tempe Foundation.Google Scholar
Kiers, JL, Nout, MJR, Rombouts, FM, van Andel, EE, Nabuur, MJA & van der Meulen, J (2006) Effect of processed and fermented soyabeans on net absorption in enterotoxigenic Escherichia coli-infected piglet small intestine. Br J Nutr 95, 11931198.CrossRefGoogle ScholarPubMed
Kiers, JL, Meijer, JC, Nout, MJR, Rombouts, FM, Nabuurs, MJA & van der Meulen, J (2003) Effect of fermented soya beans on diarrhoea and feed efficiency in weaned piglets. J Appl Microbiol 95, 545552.CrossRefGoogle ScholarPubMed
Kalavi, FN, Muroki, NM, Omwega, AM & Mwadime, RK (1996) Effect of tempe-yellow maize porridge and milk-yellow maize porridge on growth rate, diarrhoea and duration of rehabilitation of malnourished children. East Afr Med J 73, 427431.Google ScholarPubMed
Karyadi, D & Lukito, W (1996) Beneficial effects of tempeh in disease prevention and treatment. Nutr Rev 54, S94S98.CrossRefGoogle ScholarPubMed
Karyadi, D & Lukito, W (2000) Functional food and contemporary nutrition–health paradigm: tempeh and its potential beneficial effects in disease prevention and treatment. Nutrition 16, 697.CrossRefGoogle ScholarPubMed
Nout, MJR, de Dreu, MA, Zuurbier, AM & Bonants van Laarhoven, TMG (1987) Ecology of controlled soybean acidification for tempe manufacture. Food Microbiol 4, 165–172.CrossRefGoogle Scholar
Kiers, JL, Nout, MJR & Rombouts, FM (2000) In vitro digestibility of processed and fermented soya bean, cowpea and maize. J Sci Food Agric 80, 13251331.3.0.CO;2-K>CrossRefGoogle Scholar
Sellwood, R, Gibbons, RA, Jones, GW & Rutter, JM (1975) Adhesion of enteropathogenic Escherichia coli to pig intestinal brush borders: the existence of two pig phenotypes. J Med Microbiol 8, 405–411.CrossRefGoogle ScholarPubMed
Nabuur, MJA, Hoogendoorn, A, van Zijderveld, FG & van der Klis, JD (1993) A long-term perfusion test to measure net absorption in the small intestine of weaned pigs. Res Vet Sci 55, 108–114.CrossRefGoogle Scholar
Go, JT, Harper, RG, Sia, CG, Teichberg, S & Wapnir, RA (1994) Oral rehydration solutions: increased water and sodium absorption by addition of a viscosity-enhancing agent in a rat model of chronic osmotic diarrhea. J Pediatr Gastroenterol Nutr 19, 410416.Google Scholar
Wapnir, RA, Wingertzahn, MA & Teichberg, S (1997) Cellulose derivatives and intestinal absorption of water and electrolytes: potential role in oral rehydration solutions. Proc Soc Exp Biol Med 215, 275–280.CrossRefGoogle ScholarPubMed
Kiers, JL, Hoogendoorn, A, Nout, MJR, Rombouts, FM, Nabuur, MJA & van der Meulen, J (2006) Effect of osmolality on net fluid absorption in non-infected and ETEC-infected piglet small intestinal segments. Res Vet Sci 81, 274279.CrossRefGoogle ScholarPubMed
Farthing, MJ (1994) Oral rehydration therapy. Pharmacol Ther 64, 477492.CrossRefGoogle ScholarPubMed
Thillainayagam, AV, Hunt, JB & Farthing, MJ (1998) Enhancing clinical efficacy of oral rehydration therapy: is low osmolality the key? Gastroenterology 114, 197–210.CrossRefGoogle ScholarPubMed
Chandler, DS & Mynott, TL (1998) Bromelain protects piglets from diarrhoea caused by oral challenge with K88 positive enterotoxigenic Escherichia coli. Gut 43, 196202.CrossRefGoogle ScholarPubMed
Mynott, TL, Luke, RK & Chandler, DS (1996) Oral administration of protease inhibits enterotoxigenic Escherichia coli receptor activity in piglet small intestine. Gut 38, 28–32.CrossRefGoogle ScholarPubMed
Mynott, TL, Guandalini, S, Raimondi, F & Fasano, A (1997) Bromelain prevents secretion caused by Vibrio cholerae and Escherichia coli enterotoxins in rabbit ileum in vitro. Gastroenterology 113, 175184.CrossRefGoogle ScholarPubMed
Takeda, T, Yoshino, K, Adachi, E, Sato, Y & Yamagata, K (1999) In vitro assessment of a chemically synthesized Shiga toxin receptor analog attached to chromosorb P (Synsorb Pk) as a specific absorbing agent of Shiga toxin 1 and 2. Microbiol Immunol 43, 331337.CrossRefGoogle Scholar
Greenwood-van Meerveld, B, Tyler, K, Kuge, T & Ogata, N (1999) Anti-diarrhoeal effects of seirogan in the rat small intestine and colon examined in vitro. Aliment Pharmacol Ther 13, 97–102.CrossRefGoogle ScholarPubMed
Hor, M, Rimpler, H & Heinrich, M (1995) Inhibition of intestinal chloride secretion by proanthocyanidins from Guazuma ulmifolia. Planta Med 61, 208212.CrossRefGoogle ScholarPubMed
Mathews, CJ, MacLeod, RJ, Zheng, SX, Hanrahan, JW, Bennett, HP & Hamilton, JR (1999) Characterization of the inhibitory effect of boiled rice on intestinal chloride secretion in guinea pig crypt cells. Gastroenterology 116, 13421347.CrossRefGoogle ScholarPubMed
Wapnir, RA, Wingertzahn, MA, Moyse, J & Teichberg, S (1998) Proabsorptive effects of modified tapioca starch as an additive of oral rehydration solutions. J Pediatr Gastroenterol Nutr 27, 17–22.Google ScholarPubMed
Wingertzahn, MA, Teichberg, S & Wapnir, RA (1999) Modified starch enhances absorption and accelerates recovery in experimental diarrhea in rats. Pediatr Res 45, 397402.CrossRefGoogle ScholarPubMed
Turvill, JL, Wapnir, RA, Wingertzahn, MA, Teichberg, S & Farthing, MJ (2000) Cholera toxin-induced secretion in rats is reduced by a soluble fiber, gum arabic. Dig Dis Sci 45, 946951.CrossRefGoogle ScholarPubMed
Wapnir, RA, Wingertzahn, MA, Moyse, J & Teichberg, S (1997) Gum arabic promotes rat jejunal sodium and water absorption from oral rehydration solutions in two models of diarrhea. Gastroenterology 112, 19791985.CrossRefGoogle ScholarPubMed
Wapnir, RA, Teichberg, S, Go, JT, Wingertzahn, MA & Harper, RG (1996) Oral rehydration solutions: enhanced sodium absorption with gum arabic. J Am Coll Nutr 15, 377–382.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 Fluid loss upon enterotoxigenic Escherichia coli (ETEC) infection after perfusion with saline, pre-digested tempeh and its supernatant. Values are means with their standard errors depicted by vertical bars. a,b Mean values with unlike superscript letters were significantly different (P < 0·05).

Figure 1

Fig. 2 High-performance size-exclusion chromatography elution patterns of supernatant of pre-digested tempeh (●) and the permeate (□) and retentate (○) fraction obtained after ultra-filtration. ↓ , Molecular weights of dextran standards.

Figure 2

Table 1 DM, nitrogen, sodium and chloride content and osmolality of the pre-digested supernatant and the permeate and retentate fractions obtained after ultra-filtration (Mean values with their standard errors)

Figure 3

Fig. 3 Net fluid absorption in non-infected (□) and enterotoxigenic Escherichia coli-infected (■) segments perfused with saline and tempeh supernatant, permeate and retentate. Values are means with their standard errors depicted by bars. There was an inverse linear relationship between osmolality and net fluid absorption for non-infected segments (net fluid absorption = 1091 − 1·45 × osmolality; r2 0·87).

Figure 4

Table 2 Average net absorption of sodium, chloride and solutes after perfusion with saline and tempeh supernatant, permeate and retentate (Mean values with their standard errors)

Figure 5

Fig. 4 High-performance size-exclusion chromatography elution pattern of the supernatant of undigested (●) and pre-digested tempeh (○). ↓ , Molecular weight of dextran standards.

Figure 6

Table 3 Nitrogen content and osmolality of undigested and pre-digested supernatant of tempeh (Mean values with their standard errors)