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Effect of supplementary calcium phosphate on plasma gastrointestinal hormones in a double-blind, placebo-controlled, cross-over human study

Published online by Cambridge University Press:  22 July 2013

Ulrike Trautvetter
Affiliation:
Department of Nutritional Physiology, Institute of Nutrition, Friedrich Schiller University of Jena, Dornburger Straße 24, D-07743Jena, Germany
Gerhard Jahreis*
Affiliation:
Department of Nutritional Physiology, Institute of Nutrition, Friedrich Schiller University of Jena, Dornburger Straße 24, D-07743Jena, Germany
*
*Corresponding author: Professor G. Jahreis, fax +49 3641/949612, email [email protected]
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Abstract

Gastrointestinal hormones and Ca are associated with bone metabolism. The objective of the present human study was to determine the effect of calcium phosphate on the postprandial circulation of gastrointestinal hormones. A total of ten men participated in the present double-blind, placebo-controlled, cross-over study. The participants were divided into two groups. Of these, one group consumed bread enriched with 1 g Ca (pentacalcium hydroxy-triphosphate, CaP) daily for 3 weeks. The other group consumed placebo bread. After 2 weeks of washout, the intervention was changed between the groups for another 3 weeks. The subjects consumed a defined diet at the beginning (single administration) and at the end (repeated administration) of the intervention periods, and blood samples were drawn at 0, 30, 60, 120, 180 and 240 min. Between 0 and 30 min, the participants consumed a test meal, with or without CaP. The concentrations of gastrointestinal hormones (glucose-dependent insulinotropic polypeptide, glucagon-like peptide (GLP) 1 and GLP2), insulin and glucose were determined. The AUC of GLP1 (total and active) and GLP2 increased significantly after the repeated CaP administrations compared with that after placebo administration. The AUC of insulin and glucose showed no differences between the CaP and placebo administrations. CaP affects the postprandial plasma concentrations of gastrointestinal hormones through the modulation of the intestinal environment, e.g. bile acids and microbiota.

Type
Full Papers
Copyright
Copyright © The Authors 2013 

Glucose-dependent insulinotropic polypeptide (GIP) and glucagon-like peptides 1 and 2 (GLP1 and GLP2) are well-known gastrointestinal hormones( Reference Phillips and Prins 1 , Reference Estall and Drucker 2 ). GIP is a peptide hormone with forty-two amino acid residues and is secreted by K-cells of the small intestine( Reference Buchan, Polak and Capella 3 , Reference Moody, Thim and Valverde 4 ). GLP1 and GLP2 are thirty-one-amino acid hormones secreted by L-cells of the small intestine( Reference Eissele, Goke and Willemer 5 ). The established function of GIP and GLP1 is lowering of glucose levels after ingestion of carbohydrates, proteins and fat and is based on insulin stimulation in the pancreas( Reference Phillips and Prins 1 ). In addition, both GIP and GLP1 receptors have been found in many other human organs, e.g. brain, bone, adipose tissue and heart( Reference Seino, Fukushima and Yabe 6 ). GLP2 has several physiological functions such as decreasing gastric acid secretion, inhibiting antral gastric emptying, up-regulating intestinal blood flow and exerting trophic effects on the intestinal mucosa as well as positive effects on nutrient absorption( Reference Jeppesen, Lund and Gottschalck 7 ).

GIP together with GLP1 and GLP2 is associated with bone metabolism. GIP stimulates bone formation by inhibiting the apoptosis of osteoblasts( Reference Yamada, Miyawaki and Tsukiyama 8 ). Furthermore, GIP decreases both the activity of alkaline phosphatase in osteoblast-like cells and the expression of collagen type 1( Reference Tsukiyama, Yamada and Yamada 9 ). GLP1 has no direct effect on bone remodelling cells, although indirect mechanisms through the up-regulation of calcitonin have been described( Reference Yamada, Yamada and Tsukiyama 10 ). A subcutaneous injection of GLP2 in postmenopausal women results in a decrease in the levels of bone resorption markers( Reference Henriksen, Alexandersen and Bjarnason 11 , Reference Henriksen, Alexandersen and Hartmann 12 ).

Since dietary Ca has beneficial effects on bone metabolism( Reference Heaney, Recker and Watson 13 , Reference Bonjour 14 ) and GIP, GLP1 and GLP2 are associated with bone metabolism, the aim of the present study was to determine the interaction between calcium phosphate and gastrointestinal hormones.

Subjects and methods

Supplement

For the purposes of supplementation, we used pentacalcium hydroxy-triphosphate (Ca5(PO4)3OH; Chemische Fabrik Budenheim KG) in the present study. CaP was incorporated into whole-wheat bread to achieve an additional Ca intake of 1 g/d. The participants consumed approximately 135 g of this bread daily. Placebo bread was prepared exactly in the same manner, but without the CaP supplement.

Subjects

The study was conducted between July and September 2010 in the Institute of Nutrition, Department of Nutritional Physiology, at the Friedrich Schiller University, Jena. A total of ten omnivorous men participated in the present double-blind, placebo-controlled, cross-over study. Eligibility criteria for the participants included age between 20 and 35 years and good physical health. Furthermore, the participants had to stay at the blood-withdrawal centre for at least 5 h between 07.30 and 12.30 hours. The volunteers were provided with detailed information regarding purpose, course and possible risks involved in the study. The present study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving human subjects were approved by the Ethical Committee of the Friedrich Schiller University, Jena (no. 2833-05/10). Written informed consent was obtained from all the subjects. Of the initial ten volunteers, one participant dropped out due to personal reasons. The study flow chart and the baseline characteristics of the nine participants have been published previously( Reference Trautvetter, Kiehntopf and Jahreis 15 ). Briefly, the participants who completed the study were aged 27 (sd 4) years and had a BMI of 23·1 (sd 2·3) kg/m2. The main study outcomes comprised blood concentrations of GLP1 (total and active), GLP2, GIP, insulin and glucose. The present trial was registered at www.clinicaltrials.gov (identifier: NCT01296997).

Study design

The details of the study design have been published previously( Reference Trautvetter, Kiehntopf and Jahreis 15 ). The participants were divided into two groups. For a period of 3 weeks, one group consumed bread containing CaP, whereas the other group consumed the placebo product. This was followed by a 2-week washout phase. Thereafter, the intervention was changed between the two groups for a further 3 weeks. Thus, the study design allowed every participant to act as his own control. The intervention periods were divided into two parts. Blood samples were collected from the study participants at the beginning of the study after a single consumption of supplemented bread or placebo (single administration). Thereafter, blood was collected at the end of the 3-week study period, during which the participants consumed either supplemented bread or placebo on a daily basis (repeated administration). Consequently, the study entailed four types of administrations: single CaP administration; single placebo administration; repeated CaP administration; repeated placebo administration. In addition, the participants consumed a defined diet for 3 d before each blood sample was collected.

The defined diet, containing the complete food supply for 3 d, was prepared and pre-weighed in the study centre. The subjects were instructed to consume only the food that was provided. Any food residues were weighed and food intake was calculated.

Fasting blood samples were collected from the study participants at the Institute of Transfusion Medicine, Jena University Hospital. Blood samples were drawn after 0, 30, 60, 120, 180 and 240 min, immediately cooled and transported to the study centre.

Between the time points 0 and 30 min, the participants consumed a test meal. The test meal consisted of bread with or without CaP (according to the intervention), 20 g butter, 25 g ham, 15 g sweet hazelnut spread and a banana. During the 240 min time point, the participants were allowed to drink water ad libitum.

Sample preparation

Samples of each food component of the defined diet were frozen and stored at − 20°C until analysis.

For the analysis of the gastrointestinal hormones GLP1 (total and active), GIP and GLP2, blood was collected in EDTA-coated tubes, to which dipeptidyl peptidase-IV inhibitor (Millipore) was added before sampling. After centrifugation at 1000  g for 10 min at 8°C, plasma was aliquoted and frozen at − 80°C. For glucose analysis, blood was collected in EDTA-fluoride tubes, centrifuged at 2000  g for 10 min at 20°C, aliquoted and analysed. Insulin analysis was performed using serum immediately after blood sampling. Aliquots were frozen at − 80°C until analysis.

Food analysis

The intake of energy, fat, proteins and carbohydrates was verified using the Prodi® 5.4 software (Nutri-Science GmbH). For the intake of minerals, the respective contents in the provided foods were analysed instead of using the calculation software. Mineral contents of all the food samples were determined employing the iCAP 6000 ICP Spectrometer (Thermo Scientific). Before analysis, the samples were ashed at 525°C. The ash was dissolved in HCl (25 %) and diluted with distilled water.

Biochemical analyses

The concentration of total GIP was determined using ELISA (IBL) according to the manufacturer's instructions. The GIP assay was specific to the active form GIP 1–42 and had a cross-reactivity of about 18 % to the inactive form GIP 3–42. The intra- and inter-assay CV for GIP were < 5 and < 7 %, respectively. Blood samples collected at time points 30, 60 and 120 min were diluted with a buffer (1:5).

The concentrations of total GLP1 (7–36 and 9–36), active GLP1 (7–36) and GLP2 were determined using ELISA (ALPCO Diagnostics) according to the instructions given in the manual. The total GLP1 assay was 100 % specific to GLP1 7–36 and 9–36 and < 0·1 % specific to GLP1 9–37, 7–37 and 1–36, GLP2 and glucagon. The intra- and inter-assay CV for total GLP1 were < 5 and < 10 %, respectively. The active GLP1 assay was 100 % specific to GLP1 7–36 and < 0·1 % specific to GLP1 9–36, 9–37, 7–37 and 1–36, GLP2 and glucagon. The intra- and inter-assay CV for active GLP1 were < 6 and < 6 %, respectively. The GLP2 assay was highly specific to human GLP2 and showed no cross-reactivity with glucagon or GLP1. The intra- and inter-assay CV for GLP2 were < 5 and < 17 %, respectively.

The concentration of glucose was determined by means of the autoanalyser ARCHITECT C16000 (Abbott) according to the methods of the Institute of Clinical Chemistry and Laboratory Medicine, Jena University Hospital. The intra- and inter-assay CV for glucose were < 2 and < 3 %, respectively.

The concentration of insulin was measured using a two-site sandwich immunoassay employing the ADVIA Centaur test instrument (Siemens) according to the methods of the Institute of Clinical Chemistry and Laboratory Medicine, Jena University Hospital, Friedrich Schiller University Jena. Proinsulin, C-peptide, gastrin-1, glucagon and secretin had no significant effect on insulin values. The intra- and inter-assay CV for insulin were < 5 and < 6 %, respectively.

Statistical analysis

Samples from each participant were coded to protect volunteer identity and to mask treatment groups during the analysis. All values given in the tables are expressed as means and standard deviations. For reasons of clarity and comprehensibility, values in the figures are expressed only as means. Statistical analysis was performed using the statistical software package PASW Statistics 18 (SPSS, Inc.). Differences were considered significant at P≤ 0·05. The effect of time was tested, comparing with baseline, using paired Student's t test. The effect of supplementation was tested using paired Student's t test. The sample size for Ca and phosphate was nine. The results for GIP are given for eight subjects due to analytical problems with the concentration of GIP of one subject.

Results

The nutrient intakes of the test meal and the defined diet have been published previously( Reference Trautvetter, Kiehntopf and Jahreis 15 ). The additional intakes of Ca and P from the CaP bread were 1104 and 519 mg/d, respectively.

Gastrointestinal hormones

The concentrations and the AUC of total GLP1, active GLP1, GLP2 and GIP are shown in Fig. 1.

Fig. 1 Concentrations and AUC of glucagon-like peptides (GLP) 1, GLP2 and glucose-dependent insulinotropic polypeptide (GIP). n 9 for total GLP1, active GLP1 and GLP2; n 8 for GIP. Values are means; AUC values are means, with standard deviations represented by vertical bars. ○, Placebo; ●, pentacalcium hydroxy-triphosphate (CaP) supplementation; ▲, significant differences compared with baseline after CaP supplementation (P≤ 0·05); △, significant differences compared with baseline after placebo administration (P≤ 0·05). * Mean value was significantly different from that of placebo administration (P≤ 0·05). The effects of time and supplementation were tested using paired Student's t test. □, Placebo administration; ■, CaP administration.

Total glucagon-like peptide 1

The concentration of total GLP1 increased after single CaP administration significantly from 0 to 30 min (P= 0·025), 60 min (P= 0·002), 120 min (P= 0·002) and 180 min (P= 0·043). The concentration of total GLP1 after placebo administration increased after 30 min (P= 0·039) compared with that at 0 min. After the repeated CaP administrations, the concentration of total GLP1 increased significantly after 30 min (P= 0·013), 60 min (P= 0·012) and 180 min (P= 0·006) compared with that at 0 min. After placebo administration, the concentration of total GLP1 increased after 30 min (P= 0·011), 60 min (P< 0·000), 120 min (P= 0·001), 180 min (P= 0·004) and 240 min (P= 0·024) compared with that at 0 min. At 30 min, the concentration of total GLP1 was significantly higher after CaP supplementation than after placebo administration (P= 0·005). The AUC of total GLP1 was significantly higher after the repeated CaP administrations than after placebo administration (P= 0·022; Fig. 1).

Active glucagon-like peptide 1

The concentration of active GLP1 increased significantly after single CaP administration after 30 min (P= 0·003), 60 min (P= 0·005), 120 min (P= 0·000), 180 min (P= 0·007) and 240 min (P= 0·034) compared with that at 0 min. After placebo administration, there was a significant increase after 30 min (P= 0·030) and 60 min (P= 0·025). Besides, the concentration of active GLP1 at 120 min (P= 0·026) was significantly higher after CaP administration in comparison with that after placebo administration. The repeated CaP administrations resulted in an increased concentration of active GLP1 after 30 min (P= 0·023) and 60 min (P= 0·047) compared with that at 0 min. After repeated placebo administrations, the concentration increased significantly after 30 min (P= 0·003), 60 min (P= 0·006), 120 min (P< 0·000) and 180 min (P= 0·016) in comparison with that at 0 min. The concentration after CaP supplementation was significantly higher at time point 240 min (P= 0·043) compared with that after placebo supplementation. The AUC after the repeated CaP administrations was significantly higher than that after placebo administration (P= 0·044) (Fig. 1).

Glucagon-like peptide 2

After single CaP administration, there was a slight, but significant increase in the concentration of GLP2 after 180 min (P= 0·010) and 240 min (P= 0·048) compared with that at 0 min. The single placebo as well as the repeated CaP administrations led to no significant changes. The repeated placebo administrations led to a significant increase after 30 min (P= 0·023). The AUC of GLP2 after the repeated CaP administrations was significantly higher than that after placebo administration (P= 0·032) (Fig. 1).

Glucose-dependent insulinotropic polypeptide

Both the single and repeated administrations led to an increase in the concentration of GIP (Fig. 1). There were no differences between the CaP and placebo administrations.

Glucose and insulin

Both the single and repeated administrations led to an increase in the concentrations of glucose and insulin (Fig. 2). The AUC of glucose and insulin showed no significant differences between the placebo and CaP supplementation.

Fig. 2 Concentrations and AUC of glucose and insulin. Values are means; AUC values are means (n 9), with standard deviations represented by vertical bars. ○, Placebo; ●, pentacalcium hydroxy-triphosphate (CaP) supplementation; ▲, significant differences compared with baseline after CaP supplementation (P≤ 0·05); △, significant differences compared with baseline after placebo administration (P≤ 0·05). The effects of time and supplementation were tested using paired Student's t test. □, Placebo administration; ■, CaP administration.

Discussion

Ca is often associated with bone health in the literature. Calcium phosphate, in particular, is often discussed in this regard due to its intestinal actions with respect to the formation of amorphous calcium phosphate and the precipitation of intestinal substances such as bile or fatty acids( Reference Lapre, De Vries and Van der Meer 16 Reference Van der Meer, Welberg and Kuipers 18 ). In the present study, the effect of CaP on the secretion of gastrointestinal hormones was determined.

To the best of our knowledge, there are no human intervention studies available in the literature examining the role of calcium phosphate in the secretion of gastrointestinal hormones. Only Lorenzen et al. ( Reference Lorenzen, Nielsen and Holst 19 ) investigated the effect of dietary Ca or supplementary Ca (calcium carbonate) intake on postprandial fat metabolism, appetite and subsequent energy intake. Although the study showed a significant interaction between meals and time of GLP1 secretion, according to the authors, this association was due to an inexplicably high concentration of GLP1 after 60 min and was not influenced by the Ca supplement( Reference Lorenzen, Nielsen and Holst 19 ). Nevertheless, Ca and the gastrointestinal hormones GIP, GLP1 and GLP2 are associated with bone metabolism( Reference Yamada, Miyawaki and Tsukiyama 8 , Reference Yamada, Yamada and Tsukiyama 10 , Reference Reid, Cornish and Baldock 20 , Reference Wong, Baldock and Herzog 21 ). There are two means by which Ca could influence the secretion of gastrointestinal hormones after meal ingestion: directly following the consumption of a Ca-rich meal and indirectly through the modulation of the intestinal environment after long-term Ca administration. Tsukiyama et al. ( Reference Tsukiyama, Yamada and Yamada 9 ) determined that GIPR knockout mice had similar concentrations of plasma Ca before meal ingestion but higher levels after meal ingestion compared with normal mice. The authors assumed that GIP directly links dietary Ca to Ca deposition in bone( Reference Tsukiyama, Yamada and Yamada 9 ). This mechanism has not been explained to date, and it is not known whether Ca influences the secretion of gastrointestinal hormones or vice versa. Furthermore, Toyota et al. ( Reference Toyota, Nakanome and Akai 22 ) elucidated that hypercalcaemia might have stimulatory effects on glucose-induced GIP release. These two publications point to a direct effect of Ca on the secretion of gastrointestinal hormones. However, based on the results of the present study, a direct effect can be excluded, as there was no difference between the single CaP and placebo administrations. Moreover, the supplementation did not lead to a hypercalcaemic status( Reference Trautvetter, Kiehntopf and Jahreis 15 ).

Significant increases in the concentrations of gastrointestinal hormones were observed after the repeated CaP administrations. Thus, an indirect effect of CaP is plausible. Several studies have shown the ability of CaP to form an amorphous calcium phosphate complex that is able to precipitate intestinal substances, such as fatty acids and bile acids( Reference Ditscheid, Keller and Jahreis 17 , Reference Trautvetter, Ditscheid and Kiehntopf 23 , Reference Govers, Termont and Van Aken 24 ). The formation and precipitation lead to several physiological changes in the human gut, e.g. modulation of microbiota and bile acid profile( Reference Trautvetter, Ditscheid and Kiehntopf 23 , Reference Ditscheid, Keller and Jahreis 25 Reference Van der Meer, Termont and De Vries 28 ). Katsuma et al. ( Reference Katsuma, Hirasawa and Tsujimoto 29 ) observed that bile acids promote the secretion of GLP1 in a murine enteroendocrine cell line STC-1 through a G protein-coupled receptor, TGR5. Furthermore, in a randomised controlled study carried out by Beysen et al. ( Reference Beysen, Murphy and Deines 30 ), the effect of bile acid sequestrants on glucose metabolism was determined in patients with type 2 diabetes. Bile acid sequestrants (e.g. colesevelam and cholestyramine) form non-absorbable complexes with bile acids in the gastrointestinal tract, which leads to the interruption of their enterohepatic circulation, thereby promoting their faecal excretion( Reference Brufau, Stellaard and Prado 31 ). Bile acid sequestrants are used as therapeutic agents for lowering LDL-cholesterol levels. In the study of Beysen et al. ( Reference Beysen, Murphy and Deines 30 ), the bile acid sequestrant colesevelam increased the concentrations of total GLP1 and GIP and the synthesis of cholesterol and bile acids and decreased the concentration of fibroblast growth factor-19. The authors assumed that bile acids activate the TGR5 receptor, which is expressed in enteroendocrine L-cells, and stimulate the secretion of GLP1. The authors supposed either a link between the composition of the bile acid pool or the change to a more hydrophilic bile acid pool by colesevelam to be responsible for these mechanisms( Reference Brufau, Stellaard and Prado 31 ). In the present study, CaP acted as a bile acid sequestrant. In fact, the ability of amorphous calcium phosphate to precipitate bile acids in the intestine has been reported previously by in vitro ( Reference Govers, Termont and Van Aken 24 , Reference Van der Meer, Termont and De Vries 28 ) and in vivo ( Reference Van der Meer, Welberg and Kuipers 18 ) studies. Furthermore, in a double-blind, placebo-controlled, cross-over study, Ditscheid et al. ( Reference Ditscheid, Keller and Jahreis 25 ) showed a significant increase in the excretion of bile acids after CaP supplementation compared with that after placebo supplementation and linked this to the precipitation of bile acids to amorphous calcium phosphate. The indirect effect of CaP via amorphous calcium phosphate is supported by the fact that only GLP1 and GLP2, but not GIP, were influenced significantly. The formation of amorphous calcium phosphate and the interaction with bile acids increase during the gastrointestinal passage (pH dependent)( Reference Van der Meer and De Vries 32 ). Therefore, CaP may influence only the gastrointestinal hormones that are secreted in the distal small intestine (GLP1 and GLP2).

Another explanation for the increased secretion of gastrointestinal hormones after repeated CaP supplementation is the modulation of the intestinal microbiota( Reference Trautvetter, Ditscheid and Kiehntopf 23 , Reference Bovee-Oudenhoven, Wissink and Wouters 26 ). Through a change in the microbiota, there may be an increase in SCFA production. SCFA can stimulate the release of GLP2 in the gut of patients with short bowel syndrome( Reference Tappenden, Albin and Bartholome 33 ). Additionally, there are hints in the literature that point to an association between dietary prebiotics and a rise in the concentrations of gastrointestinal hormones due to an increase of colonic fermentation products( Reference Diamant, Blaak and De Vos 34 , Reference Cani, Lecourt and Dewulf 35 ).

The changes in the secretion of gastrointestinal hormones after repeated CaP supplementation did not affect insulin and glucose metabolism. Both insulin and glucose showed a normal postprandial response, as published in the literature( Reference Frost, Brynes and Dhillo 36 Reference Thomsen, Rasmussen and Lousen 38 ). Different gastrointestinal hormones have diverse target sites and, thus, it is likely that this modulation affects actions such as bone metabolism.

In conclusion, this is the first human study to investigate the effect of supplemental CaP on the postprandial concentrations of GIP, GLP1 and GLP2. From the present results, we conclude that CaP stimulates the secretion of gastrointestinal hormones through the modulation of the intestinal environment.

Acknowledgements

The authors thank Dr Lars Müller, Manja Dittrich and Ute Helms for their technical and scientific assistance. They also thank Nasim Kroegel for English language editing.

The authors thank VCI (Verband der Chemischen Industrie e.V.) for providing financial support and for supplying the supplement. VCI had no role in the design, analysis or writing of this article.

Neither of the authors had a personal or financial conflict of interest.

U. T. conducted the research, analysed the data, performed the statistical analysis and wrote the manuscript. U. T. and G. J. designed the research and had primary responsibility for the final content. All authors were responsible for the critical revision of the manuscript.

References

1 Phillips, LK & Prins, JB (2011) Update on incretin hormones. Ann N Y Acad Sci 1243, E55E74.Google Scholar
2 Estall, JL & Drucker, DJ (2006) Glucagon-like peptide-2. Annu Rev Nutr 26, 391411.Google Scholar
3 Buchan, AMJ, Polak, JM, Capella, C, et al. (1978) Electronimmunocytochemical evidence for the K cell localization of gastric inhibitory polypeptide (GIP) in man. Histochemistry 56, 3744.Google Scholar
4 Moody, AJ, Thim, L & Valverde, I (1984) The isolation and sequencing of human gastric inhibitory peptide (GIP). FEBS Lett 172, 142148.Google Scholar
5 Eissele, R, Goke, R, Willemer, S, et al. (1992) Glucagon-like peptide-1 cells in the gastrointestinal tract and pancreas of rat, pig and man. Eur J Clin Invest 22, 283291.CrossRefGoogle Scholar
6 Seino, Y, Fukushima, M & Yabe, D (2010) GIP and GLP-1, the two incretin hormones: similarities and differences. J Diabetes Invest 1, 823.CrossRefGoogle ScholarPubMed
7 Jeppesen, PB, Lund, P, Gottschalck, IB, et al. (2009) Short bowel patients treated for two years with glucagon-like peptide 2 (GLP-2): compliance, safety, and effects on quality of life. Gastroenterol Res Pract 2009, article ID 425759.Google Scholar
8 Yamada, Y, Miyawaki, K, Tsukiyama, K, et al. (2006) Pancreatic and extrapancreatic effects of gastric inhibitory polypeptide. Diabetes 55, S86S91.Google Scholar
9 Tsukiyama, K, Yamada, Y, Yamada, C, et al. (2006) Gastric inhibitory polypeptide as an endogenous factor promoting new bone formation after food ingestion. Mol Endocrinol 20, 16441651.CrossRefGoogle ScholarPubMed
10 Yamada, C, Yamada, Y, Tsukiyama, K, et al. (2008) The murine glucagon-like peptide-1 receptor is essential for control of bone resorption. Endocrinology 149, 574579.Google Scholar
11 Henriksen, DB, Alexandersen, P, Bjarnason, NH, et al. (2003) Role of gastrointestinal hormones in postprandial reduction of bone resorption. J Bone Miner Res 18, 21802189.CrossRefGoogle ScholarPubMed
12 Henriksen, DB, Alexandersen, P, Hartmann, B, et al. (2007) Disassociation of bone resorption and formation by GLP-2 – a 14-day study in healthy postmenopausal women. Bone 40, 723729.Google Scholar
13 Heaney, RP, Recker, RR, Watson, P, et al. (2010) Phosphate and carbonate salts of calcium support robust bone building in osteoporosis. Am J Clin Nutr 92, 101105.CrossRefGoogle ScholarPubMed
14 Bonjour, JP (2011) Calcium and phosphate: a duet of ions playing for bone health. J Am Coll Nutr 30, 438S448S.Google Scholar
15 Trautvetter, U, Kiehntopf, M & Jahreis, G (2013) Postprandial effects of calcium phosphate supplementation on plasma concentration-double-blind, placebo-controlled cross-over human study. Nutr J 12, 30.CrossRefGoogle ScholarPubMed
16 Lapre, JA, De Vries, HT & Van der Meer, R (1991) Dietary calcium phosphate inhibits cytotoxicity of fecal water. Am J Physiol Gastrointest Liver Physiol 261, G907G912.CrossRefGoogle ScholarPubMed
17 Ditscheid, B, Keller, S & Jahreis, G (2005) Cholesterol metabolism is affected by calcium phosphate supplementation in humans. J Nutr 135, 16781682.Google Scholar
18 Van der Meer, R, Welberg, JWM, Kuipers, F, et al. (1990) Effects of supplemental dietary calcium on the intestinal association of calcium, phosphate, and bile-acids. Gastroenterology 99, 16531659.Google Scholar
19 Lorenzen, JK, Nielsen, S, Holst, JJ, et al. (2007) Effect of dairy calcium or supplementary calcium intake on postprandial fat metabolism, appetite, and subsequent energy intake. Am J Clin Nutr 85, 678687.CrossRefGoogle ScholarPubMed
20 Reid, IR, Cornish, J & Baldock, PA (2006) Nutrition-related peptides and bone homeostasis. J Bone Miner Res 21, 495500.Google Scholar
21 Wong, IP, Baldock, PA & Herzog, H (2010) Gastrointestinal peptides and bone health. Curr Opin Endocrinol Diabetes Obes 17, 4450.Google Scholar
22 Toyota, T, Nakanome, C, Akai, H, et al. (1982) Release of gastric inhibitory polypeptide (GIP) during calcium infusion and in hyperparathyroidism. Regul Pept 4, 112.CrossRefGoogle ScholarPubMed
23 Trautvetter, U, Ditscheid, B, Kiehntopf, M, et al. (2012) A combination of calcium phosphate and probiotics beneficially influences intestinal lactobacilli and cholesterol metabolism in humans. Clin Nutr 31, 230237.CrossRefGoogle ScholarPubMed
24 Govers, MJ, Termont, DS, Van Aken, GA, et al. (1994) Characterization of the adsorption of conjugated and unconjugated bile acids to insoluble, amorphous calcium phosphate. J Lipid Res 35, 741748.CrossRefGoogle ScholarPubMed
25 Ditscheid, B, Keller, S & Jahreis, G (2009) Faecal steroid excretion in humans is affected by calcium supplementation and shows gender-specific differences. Eur J Nutr 48, 2230.Google Scholar
26 Bovee-Oudenhoven, IM, Wissink, ML, Wouters, JT, et al. (1999) Dietary calcium phosphate stimulates intestinal lactobacilli and decreases the severity of a salmonella infection in rats. J Nutr 129, 607612.Google Scholar
27 Govers, MJ, Termont, DS, Lapre, JA, et al. (1996) Calcium in milk products precipitates intestinal fatty acids and secondary bile acids and thus inhibits colonic cytotoxicity in humans. Cancer Res 56, 32703275.Google Scholar
28 Van der Meer, R, Termont, DS & De Vries, HT (1991) Differential effects of calcium ions and calcium phosphate on cytotoxicity of bile acids. Am J Physiol 260, G142G147.Google ScholarPubMed
29 Katsuma, S, Hirasawa, A & Tsujimoto, G (2005) Bile acids promote glucagon-like peptide-1 secretion through TGR5 in a murine enteroendocrine cell line STC-1. Biochem Biophys Res Commun 329, 386390.Google Scholar
30 Beysen, C, Murphy, EJ, Deines, K, et al. (2012) Effect of bile acid sequestrants on glucose metabolism, hepatic de novo lipogenesis, and cholesterol and bile acid kinetics in type 2 diabetes: a randomised controlled study. Diabetologia 55, 432442.CrossRefGoogle ScholarPubMed
31 Brufau, G, Stellaard, F, Prado, K, et al. (2010) Improved glycemic control with colesevelam treatment in patients with type 2 diabetes is not directly associated with changes in bile acid metabolism. Hepatology 52, 14551464.CrossRefGoogle Scholar
32 Van der Meer, R & De Vries, HT (1985) Differential binding of glycine-conjugated and taurine-conjugated bile-acids to insoluble calcium-phosphate. Biochem J 229, 265268.Google Scholar
33 Tappenden, KA, Albin, DM, Bartholome, AL, et al. (2003) Glucagon-like peptide-2 and short-chain fatty acids: a new twist to an old story. J Nutr 133, 37173720.Google Scholar
34 Diamant, M, Blaak, EE & De Vos, WM (2011) Do nutrient–gut-microbiota interactions play a role in human obesity, insulin resistance and type 2 diabetes? Obes Rev 12, 272281.Google Scholar
35 Cani, PD, Lecourt, E, Dewulf, EM, et al. (2009) Gut microbiota fermentation of prebiotics increases satietogenic and incretin gut peptide production with consequences for appetite sensation and glucose response after a meal. Am J Clin Nutr 90, 12361243.Google Scholar
36 Frost, GS, Brynes, AE, Dhillo, WS, et al. (2003) The effects of fiber enrichment of pasta and fat content on gastric emptying, GLP-1, glucose, and insulin responses to a meal. Eur J Clin Nutr 57, 293298.Google Scholar
37 Greenway, F, O'Neil, CE, Stewart, L, et al. (2007) Fourteen weeks of treatment with Viscofiber increased fasting levels of glucagon-like peptide-1 and peptide-YY. J Med Food 10, 720724.Google Scholar
38 Thomsen, C, Rasmussen, O, Lousen, T, et al. (1999) Differential effects of saturated and monounsaturated fatty acids on postprandial lipemia and incretin responses in healthy subjects. Am J Clin Nutr 69, 11351143.Google Scholar
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Fig. 1 Concentrations and AUC of glucagon-like peptides (GLP) 1, GLP2 and glucose-dependent insulinotropic polypeptide (GIP). n 9 for total GLP1, active GLP1 and GLP2; n 8 for GIP. Values are means; AUC values are means, with standard deviations represented by vertical bars. ○, Placebo; ●, pentacalcium hydroxy-triphosphate (CaP) supplementation; ▲, significant differences compared with baseline after CaP supplementation (P≤ 0·05); △, significant differences compared with baseline after placebo administration (P≤ 0·05). * Mean value was significantly different from that of placebo administration (P≤ 0·05). The effects of time and supplementation were tested using paired Student's t test. □, Placebo administration; ■, CaP administration.

Figure 1

Fig. 2 Concentrations and AUC of glucose and insulin. Values are means; AUC values are means (n 9), with standard deviations represented by vertical bars. ○, Placebo; ●, pentacalcium hydroxy-triphosphate (CaP) supplementation; ▲, significant differences compared with baseline after CaP supplementation (P≤ 0·05); △, significant differences compared with baseline after placebo administration (P≤ 0·05). The effects of time and supplementation were tested using paired Student's t test. □, Placebo administration; ■, CaP administration.