1. Introduction

nutrients

Nutrients

2072-6643

MDPI

10.3390/nu5020396

nutrients-05-00396

Article

Soluble Fiber Dextrin and Soluble Corn Fiber Supplementation Modify Indices of Health in Cecum and Colon of Sprague-Dawley Rats

Knapp

Brenda K.

1 Bauer

Laura L.

1 Swanson

Kelly S.

1 Tappenden

Kelly A.

2 Fahey

George C.

Jr. 1 de Godoy

Maria R. C.

1 *

1 Department of Animal Sciences, University of Illinois, 1207 W. Gregory Drive, Urbana, IL 61801, USA; E-Mails: bknapp11@gmail.com (B.K.K.); llbauer@illinois.edu (L.L.B.); ksswanso@illinois.edu (K.S.S.); gcfahey@illinois.edu (G.C.F.) 2 Department of Food Science and Human Nutrition, University of Illinois, 905 S. Goodwin Avenue, Urbana, IL 61801, USA; E-Mail: tappende@illinois.edu

* Author to whom correspondence should be addressed; E-Mail: mgodoy2@illinois.edu; Tel.:+1-217-333-7348; Fax: +1-217-333-7861.

04 02 2013

02 2013

5 2 396 410 28 11 2012 18 01 2013 21 01 2013

2013

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution license (http://creativecommons.org/licenses/by/3.0/).

The objective of this study was to evaluate health outcomes resulting from dietary supplementation of novel, low-digestible carbohydrates in the cecum and colon of Sprague-Dawley rats randomly assigned to one of four treatment groups for 21 days: 5% cellulose (Control), Pectin, soluble fiber dextrin (SFD), or soluble corn fiber (SCF). Rats fed Pectin had a higher average daily food intake, but no differences in final body weights or rates of weight gain among treatments were observed. No differences were observed in total short-chain fatty acid (SCFA) or branched-chain fatty acid (BCFA) concentrations in the cecum and colon of rats fed either SFD or SCF. The SFD and SCF treatments increased cecal propionate and decreased butyrate concentrations compared to Control or Pectin. Pectin resulted in increased BCFA in the cecum and colon. Supplementation of SFD and SCF had no effect on cecal microbial populations compared to Control. Consumption of SFD and SCF increased total and empty cecal weight but not colon weight. Gut histomorphology was positively affected by SFD and SCF. Increased crypt depth, goblet cell numbers, and acidic mucin were observed in both the cecum and colon of rats supplemented with SFD, SCF, and Pectin. These novel, low-digestible carbohydrates appear to be beneficial in modulating indices of hindgut morphology when supplemented in the diet of the rat.

cecal fermentation histomorphology soluble fiber dextrin soluble corn fiber

1. Introduction

Dietary fiber as a promoter of healthy gut function and other health benefits is well recognized [1]. However, most of the population of the United States consumes less than half the recommended concentration of dietary fiber daily [2]. This has led to a demand for the development of novel carbohydrates that have functional properties similar to those of dietary fiber but that may be incorporated more easily into a wider array of solid and liquid food matrices.

One class of carbohydrates, low-digestible carbohydrates, is becoming popular as a food ingredient, not only due to their potential to improve both the physical and chemical properties of foods, but also due to possible health benefits associated with their consumption that are similar in nature to those of dietary fiber [3]. Low-digestible carbohydrates are low molecular weight carbohydrates that resist hydrolytic activity of human digestive enzymes [4,5,6]. They pass into the colon where they are substrates for complete or partial fermentation by colonic microbiota. Fermentation results in short-chain fatty acids (SCFA) that provide colonic cells with energy and lower pH of luminal contents, stimulating a healthy environment for beneficial bacteria. Low-digestible carbohydrates also may beneficially impact the morphology of the gastrointestinal tract, especially through modulation of the mucosal layer. This layer is primarily composed of mucin glycoproteins synthesized and secreted by goblet cells that serve as a protective barrier for the epithelial cells [7]. Modulation of the mucosal layer may positively or detrimentally affect this barrier and, thus, the health of the gastrointestinal tract.

Two novel, low-digestible carbohydrates are soluble fiber dextrin (SFD) and soluble corn fiber (SCF). Soluble fiber dextrin is an indigestible dextrin produced when corn starch is treated with heat and acid, and SCF is produced by isolating an oligosaccharide-rich fraction from corn syrup. Both of these novel, low-digestible carbohydrates are produced in such a way that branching and the number of α-1,6-glycosidic bonds are increased [8,9]. Soluble fiber dextrin and SCF have been reported to have a decreased in vitro hydrolytic digestion. Also, they attenuate glycemic and insulinemic responses and have reduced energy values [10]. However, little research exists regarding these novel, low-digestible carbohydrates on indices of gut health.

The objective of this study was to determine the effects of supplementation of SFD and SCF on select indices of gut health. This was determined by measuring pH, SCFA concentrations, and microbial populations in the cecum and/or colon of rats. Total and empty cecal and colonic mass and crypt and goblet cell measurements also were taken to determine the impact of these low-digestible carbohydrates on gut morphology. It was hypothesized that SFD and SCF would enhance fermentative processes in the hindgut, positively affecting intestinal microbiota and exerting trophic effects on gut morphology.

2. Experimental Section 2.1. Animals

Forty male Sprague-Dawley rats (average initial weight, 174 ± 11 g; 6 weeks of age) were purchased from Harlan Laboratories, Inc. (Indianapolis, IN, USA). Rats were housed individually in stainless steel wire-bottom cages in a temperature and humidity controlled facility with 12 h light and dark cycles. Prior to the experiment, rats were fed for 7 days on an AIN-93G diet [11]. Rats were given free access to water. All animal care procedures were approved by the University of Illinois Institutional Animal Care and Use Committee before initiation of the experiment.

2.2. Experimental Design and Treatments

Rats were randomly assigned to one of four dietary treatments (10 rats/treatment) after the adaptation period of 7 days. Rats were given free access to pelleted diets. Four dietary treatments were utilized in this study: a control diet that was the AIN-93G diet with 5% cellulose (Control), a positive control that consisted of the AIN-93G diet with 5% pectin (high-methoxy pectin, TIC Gums, White Marsh, MD, USA) substituted for cellulose (Pectin), a treatment that consisted of the AIN-93G diet with 5% soluble fiber dextrin (Nutriose, Roquette, Keokuk, IA, USA) substituted for cellulose (SFD), and a treatment that consisted of the AIN-93G diet with 5% soluble corn fiber (Promitor^®, Tate & Lyle, Decatur, IL, USA) substituted for cellulose (SCF). All diets were prepared by Research Diets, Inc. (New Brunswick, NJ, USA). The ingredient and chemical composition of the diets is listed in Table 1. The duration of the study was 21 days. Food intake was determined daily and body weights were measured weekly.

nutrients-05-00396-t001_Table 1

Table 1

Ingredient and chemical composition of diets containing select dietary fibers and fed to rats.

Item	Control	Pectin	SFD ¹	SCF ²
Ingredient composition	% of diet
Cornstarch	39.75	39.75	39.75	39.75
Casein	20.00	20.00	20.00	20.00
Maltodextrin	13.20	13.20	13.20	13.20
Sucrose	10.00	10.00	10.00	10.00
Soybean oil	7.00	7.00	7.00	7.00
Cellulose	5.00	0.00	0.00	0.00
Pectin	0.00	5.00	0.00	0.00
SFD	0.00	0.00	5.00	0.00
SCF	0.00	0.00	0.00	5.00
Mineral mix ³	3.50	3.50	3.50	3.50
Vitamin mix ⁴	1.00	1.00	1.00	1.00
L-Cystine	0.30	0.30	0.30	0.30
Choline bitartrate	0.25	0.25	0.25	0.25
Dye	0.005	0.005	0.005	0.005
t-Butylhydroquinone	0.0014	0.0014	0.0014	0.0014
Chemical composition	% of diet
Dry matter (DM)	90.6	90.4	89.1	89.6
	% DM basis
Organic matter	97.4	97.3	97.4	97.4
Crude protein	18.7	19.5	19.3	19.2
Total dietary fiber	5.9	5.3	2.0	2.2
Acid hydrolyzed fat	6.9	6.9	7.0	7.0
Gross energy, kcal/g	4.7	4.7	4.7	4.7

¹ Soluble fiber dextrin; ² Soluble corn fiber; ³ Mineral mix = AIN-93G-MX. Mineral (g/kg): Calcium carbonate, 357.00; Potassium phosphate, 196.00; Potassium citrate, 70.78; Sodium chloride, 74.00; Potassium sulfate, 46.60; Magnesium oxide, 24.00; Ferric citrate, 6.06; Zinc carbonate, 1.65; Sodium meta-silicate, 1.45; Manganous carbonate, 0.63; Cupric carbonate, 0.30; Chromium potassium sulfate, 0.28; Boric acid, 0.08; Sodium fluoride, 0.06; Nickel carbonate, 0.03; Lithium chloride, 0.02; Sodium selenate, 0.01; Potassium iodate, 0.01; Ammonium paramolybdate, 0.008; Ammonium vanadate, 0.007; Powdered sucrose, 221.03; ⁴ Vitamin mix = AIN-93G-VX. Vitamin (mg/kg) (except as noted): Nicotinic acid, 3.00; Ca pantothenate, 1.60; Pyridoxine, 0.70; Thiamin, 0.60; Riboflavin, 0.60; Folic acid, 0.20; Biotin, 0.02; Vitamin B₁₂, 2.50; Vitamin E (500 IU/g), 15.00; Vitamin A (500,000 IU/g), 0.80; Vitamin D₃ (400,000 IU/g), 0.25; Vitamin K, 0.08; Powdered sucrose, 974.65.

2.3. Sample Collection

On day 21, rats were euthanized by placement in a CO₂ chamber. A ventral midline incision then was made and the cecum and colon were removed. Immediately after removal, cecum and colon with contents were weighed to determine total weight. pH of cecal and colonic contents was taken using a Beckman pH meter and electrode (Beckman Instruments, Inc., Fullerton, CA, USA). Aliquots of cecal and colon contents then were taken for DM, SCFA, and microbiota analysis. The SCFA aliquots were acidified with 5 mL 2 N HCl before storing at −20 °C. The aliquot for microbial analysis was sealed in a sterile cryovial, snap frozen in liquid nitrogen, and stored at −80 °C. No colonic contents were collected for microbiota analysis due to insufficient amounts of colonic digesta.

Following removal of the appropriate samples, the tissues were cleaned with water, blotted dry, and weighed to determine empty cecum and colon weights. Total cecal and colonic contents were calculated as total tissue weight with contents minus empty tissue weight. Cecal and colonic tissue from rats was collected and fixed in phosphate buffered formalin for histomorphological analysis.

2.4. Chemical Analysis

Diet samples were analyzed for dry matter (DM), organic matter (OM) [12], Leco N [12], acid hydrolyzed fat (AHF) [13,14], and gross energy (GE) (Parr Instrument Co., Moline, IL, USA). Diet samples also were analyzed for total dietary fiber (TDF) content [15]. All procedures were performed in duplicate. To maintain quality control during chemical analysis, the error between duplicate samples was determined and, if it exceeded 5%, the assay was repeated. Fresh cecal and colonic contents were analyzed for DM and pH (as indicated above), and SCFA using gas chromatography [16]. Briefly, acetate, propionate, butyrate, isobutyrate, isovalerate, and valerate concentrations were determined on the supernatant of acidified cecal and colonic contents using a Hewlett-Packard 5890A Series II gas chromatograph (Palo Alto, CA, USA) and a glass column packed with 10% SP-1200/1% H₃PO₄ on 80/100+ mesh Chromosorb WAW (Supelco, Bellefonte, PA, USA).

2.5. Microbial Analysis

Microbial populations were analyzed using methods described by Middelbos et al. [17] with minor modifications. Cecal digesta DNA was extracted from freshly collected samples that had been stored at −80 °C until analysis, using the repeated bead beater method described by Yu and Morrison [18] followed by a QIAamp DNA stool mini kit (Qiagen, Valencia, CA, USA) according to manufacturer’s instructions. Extracted DNA was quantified using a NanoDrop ND-1000 spectrophotometer (Nano-Drop Technologies, Wilmington, DE, USA). Escherichia coli, the Bifidobacterium genus, and the Lactobacillus genus were quantified using quantitative polymerase chain reaction (qPCR) and specific primers. Amplification was performed for each bacterial group within each sample according to the procedures of Deplancke and co-workers [19]. For amplification, 10 μL final volume containing 5 μL of 2× SYBR Green PCR Master Mix (Applied Biosystems, Foster City, CA, USA), 15 pmol of the forward and reverse primers of the bacteria of interest, and 5 ng of extracted cecal DNA were used. Pure cultures of each bacterium were used to create serial dilutions in triplicate of the targeted bacterial genus to obtain standard curves. Bacterial DNA was extracted from each dilution and amplified along with cecal DNA samples using a Taqman ABI PRISM 7900HT Sequence Detection System (Applied BioSystems, Foster City, CA, USA). Colony forming units (cfu) of each standard curve serial dilution were determined previously by plating on specific agars. E. coli was grown on Luria-Bertani medium, Lactobacillus on Difco Lactobacilli MRS broth (Becton, Dickenson, and Co., Sparks, MD, USA), and Bifidobacterium on Difco Reinforced Clostridial Medium (Becton, Dickenson, and Co., Sparks, MD, USA). Cycle threshold values were plotted against the standard curves for quantification (cfu/g cecal contents) of the targeted bacterial DNA from cecal samples.

2.6. Cecal and Colonic Histomorphology

Cecal and colonic sections from each rat were embedded in a paraffin block, sliced into 5 µm thick sections using a microtome, and stained. One set of slides was stained with alcian blue (AB) and periodic acid Shiff and counterstained with hematoxylin for determining crypt depth, goblet cell numbers, and mucin (acidic and neutral) components. Another set of slides was stained with high iron diamine (HID) and AB to determine sulfated and sialylated mucins; subtypes of acidic mucins. Slides were prepared and stained at the Department of Veterinary Biosciences Histology Laboratory, University of Illinois. Crypt depth, goblet cell counts, and mucin composition measurements were attempted on a minimum of 15 crypts per section. Data are presented as the average number of stained goblet cells per crypt. Digital images of tissues and measurements were taken using Axiovision LE software and an AxioCam MRc5 (Zeiss, Oberkochen, Germany).

2.7. Statistical Analyses

Data were analyzed as a completely randomized design using the Mixed Models procedure of SAS (SAS Institute, Inc., Cary, NC, USA). The model contained the fixed effect of diet and the random effect of rat. Differences among treatments were determined using a Fisher-protected least significant difference test with a Tukey adjustment to control for experiment-wise error. Reported pooled standard errors of the mean (SEM) were determined according to the Mixed Models procedure of SAS. Significant differences were accepted at a probability of P < 0.05.

3. Results 3.1. Diet Composition, Body Weight, and Food Intake

Dietary treatments were similar in DM, OM, CP, AHF, and GE composition (Table 1). Total dietary fiber concentrations were lower for the SFD and SCF diets because the TDF method used does not fully quantify low-molecular weight dietary fibers like SFD and SCF. The complete carbohydrate composition of SFD and SCF is presented in Knapp et al. [10].

Daily food intake, final body weights, and rate of weight gain are presented in Table 2. Initial body weights of the rats were similar among the groups (avg. 178.4 g) and, after 21 days on the experimental diets, the final body weights and rate of weight gain did not differ significantly. Daily food intake was approximately 16.5 g/day, with rats fed the Pectin diet having a higher (P < 0.05) daily food intake.

nutrients-05-00396-t002_Table 2

Table 2

Daily food intake, rate of weight gain, and final body weights of rats fed select dietary fibers.

Item	Treatment
Item	Control	Pectin	SFD ¹	SCF ²	SEM ³
Daily food intake, g/day	16.5 ^a	17.4 ^b	16.1 ^a	15.9 ^a	0.26
Initial body weight, g	178.2	178.8	179.3	177.4	2.09
Final body weight, g	314.6	323.8	327.4	318.5	6.01
Rate of weight gain, g/day	4.6	4.9	5.0	4.5	0.22

¹ Soluble fiber dextrin; ² Soluble corn fiber; ³ Pooled SEM; ^a,b Means in the same row with different superscript letters are different (P < 0.05).

3.2. Cecal and Colonic Weight, pH, and Dry Matter Content

Total weight, empty weight, and pH values for cecum and colon are presented in Table 3. Total weight of the cecum was dramatically increased (P < 0.05) as a result of consumption of SFD and SCF. However, this effect was not noted in the colon where all treatments resulted in a similar total colon weight. Empty cecal weight was increased (P < 0.05) compared with the Control as a result of Pectin, SFD, and SCF consumption, with values for the latter two fibers being higher than that for Pectin. Empty colonic weight was unaffected by diet. Cecal and colonic pH values were lowered (P < 0.05) by SFD and SCF. Dry matter of cecal contents was greatest for Control and SCF, intermediate for SFD, and smallest for Pectin (P < 0.05). Colon content (% DM) did not differ among dietary treatments and it was quite variable as depicted by the large SEM.

nutrients-05-00396-t003_Table 3

Table 3

Cecal and colonic total and empty weights, pH, and dry matter content values in rats fed select dietary fibers.

Item	Treatment
Item	Control	Pectin	SFD ¹	SCF ²	SEM ³
Total weight, g
Cecum	3.1 ^a	4.0 ^a	6.7 ^b	6.2 ^b	0.38
Colon	1.8	1.5	1.3	1.5	0.16
Empty weight, g
Cecum	0.9 ^a	1.2 ^b	1.6 ^c	1.3 ^c	0.08
Colon	0.9	0.9	0.9	0.9	0.07
Cecal pH	6.9 ^b	6.7 ^b	5.9 ^a	6.0 ^a	0.10
Colon pH	6.9 ^b	6.9 ^b	6.2 ^a	6.1 ^a	0.14
Cecal content, % DM	21.8 ^c	15.0 ^a	18.5 ^b	22.1 ^c	1.05
Colon content, % DM	31.3	28.4	28.4	33.9	6.77

¹ Soluble fiber dextrin; ² Soluble corn fiber; ³ Pooled SEM; ^a,b,c Means in the same row with different superscript letters are different (P < 0.05).

3.3. Histomorphology

Histomorphology data collected on rat cecum and colon are presented in Table 4.

nutrients-05-00396-t004_Table 4

Table 4

Effect of select dietary fibers on cecum and colon histomorphology of rats.

Item	Treatment
Item	Control	Pectin	SFD ¹	SCF ²	SEM ³
Cecum
Crypt depth, μm	164.6 ^a	210.6 ^b	208.8 ^b	201.5 ^b	5.46
Goblet cells (n) per crypt
Total	12.6 ^a	20.1 ^b	19.8 ^b	19.3 ^b	1.48
Acidic mucin	7.1 ^a	14.2 ^b	13.9 ^b	12.5 ^b	1.22
Mixed (acidic/neutral)	5.7	7.5	6.9	6.9	0.41
Mucin (n) per crypt
Sulfomucins	6.8	8.2	7.8	8.1	0.68
Sialomucins	5.9	6.2	6.7	6.0	0.44
Colon
Crypt depth, µm	216.5 ^a	257.5 ^b	245.4 ^b	242.7 ^b	7.94
Goblet cells (n) per crypt
Total	15.8 ^a	25.0 ^b	23.9 ^b	24.3 ^b	1.36
Acidic mucin	11.5 ^a	21.4 ^b	19.4 ^b	20.1 ^b	1.28
Mixed (acidic/neutral)	3.8	4.5	5.2	4.9	0.32
Mucin (n) per crypt
Sulfomucins	6.6 ^a	13.3 ^b	10.5 ^b	10.9 ^b	1.00
Sialomucins	10.7	10.2	9.9	10.2	0.92

¹ Soluble fiber dextrin; ² Soluble corn fiber; ³ Pooled SEM; ^a,b Means in the same row with different superscript letters are different (P < 0.05); (n) = the average number of stained goblet cells per crypt.

Crypt depth in both cecum and colon was increased (P < 0.05) in rats fed the Pectin, SFD, and SCF compared with Control. A similar pattern for goblet cell number was noted. In both cecum and colon, supplementation of Pectin, SFD, and SCF increased (P < 0.05) goblet cell numbers compared to Control.

The majority of goblet cells found in both cecum and colon crypts were found to be comprised of acidic mucin, and increased (P < 0.05) acidic mucins were found in rats fed Pectin, SFD, and SCF. These were found concentrated towards the bottom of the crypts. No goblet cells composed of only neutral mucin were observed in cecal or colonic crypts for any treatment; however, goblet cells comprised of a mixture of both acidic and neutral mucins were observed. These cells stained purple, indicating that both types of mucins were present [20]. No differences between cecum and colon or among dietary treatments were observed for mixed goblet cells. Fermentable substrates resulted in more sulfomucins relative to Control in colon but not in cecum.

3.4. Microbial Concentrations

No differences among treatments were noted in cecal concentrations of Bifidobacterium spp., Lactobacillus spp., or Escherichia coli (data not shown). Average concentration values across treatments for these microbiota were 9.7, 11.4, and 11.7 log10 cfu/g cecal DM, respectively.

3.5. Short-Chain Fatty Acids and Branched-Chain Fatty Acids

Fermentative end-product concentrations in cecal and colonic contents are presented in Table 5. Pectin resulted in increased (P < 0.05) acetate concentrations in cecal contents compared to the other treatments. Propionate concentrations were highest (P < 0.05) for SFD, with SCF and Pectin having lower (P < 0.05) concentrations. Cecal concentrations of butyrate were lowest (P < 0.05) for the SFD and SCF treatments. Pectin supplementation resulted in the highest (P < 0.05) total cecal SCFA concentration among treatments. Supplementation of SFD and SCF resulted in similar total SCFA when compared to the Control diet.

Cecal isobutyrate, valerate, and total BCFA concentrations were lower (P < 0.05) with supplementation of both SFD and SCF compared to either Control or Pectin treatments. Isovalerate concentrations were lower (P < 0.05) for the SFD and SCF treatments compared to Pectin. Pectin resulted in the highest (P < 0.05) cecal concentrations of total BCFA for all dietary treatments.

Colonic SCFA concentrations were lower overall compared to those in cecal contents. Acetate and total SCFA concentrations were higher (P < 0.05) for the Pectin treatment compared to the SCF treatment. Soluble fiber dextrin resulted in higher (P < 0.05) propionate concentrations compared to Control. Similarly to cecal SCFA, butyrate concentrations were higher (P < 0.05) for the Pectin and Control treatments compared to SFD and SCF treatments.Concentrations of BCFA were lower in the colon compared to concentrations in the cecum. Pectin resulted in higher (P < 0.05) concentrations of isobutyrate than did SFD. Isovalerate concentrations were higher (P < 0.05) for Pectin compared to Control and SCF. Pectin resulted in the highest (P < 0.05) concentrations of valerate and total BCFA compared with the other treatments.

nutrients-05-00396-t005_Table 5

Table 5

Concentrations of short-chain fatty acids (SCFA) and branched-chain fatty acids (BCFA) in cecal and colonic contents of rats fed select dietary fibers.

Item	Treatment
Item	Control	Pectin	SFD ¹	SCF ²	SEM ³
Cecal SCFA, µmol/g ⁴
Acetate	192.3 ^a	460.9 ^b	206.8 ^a	171.6 ^a	20.46
Propionate	53.0 ^a	88.1 ^b	113.5 ^c	90.4 ^b	6.33
Butyrate	52.8 ^b	60.2 ^b	13.6 ^a	14.0 ^a	5.15
Total SCFA	298.2 ^a	609.2 ^b	333.9 ^a	276.0 ^a	26.17
Cecal BCFA, µmol/g ⁴
Isobutyrate	4.5 ^b	5.3 ^b	2.7 ^a	2.2 ^a	0.44
Isovalerate	4.6 ^a,b	5.6 ^b	4.0 ^a	3.5 ^a	0.35
Valerate	5.0 ^b	8.1 ^c	1.5 ^a	1.9 ^a	0.41
Total BCFA	14.1 ^b	19.0 ^c	8.2 ^a	7.6 ^a	1.04
Colonic SCFA, µmol/g ⁴
Acetate	118.1 ^a,b	214.9 ^b	100.7 ^a,b	81.7 ^a	29.94
Propionate	29.7 ^a	50.8 ^a,b	73.9 ^b	34.1 ^a,b	11.09
Butyrate	30.3 ^b	43.6 ^b	6.7 ^a	6.3 ^a	5.86
Total SCFA	178.8 ^a,b	309.1 ^b	180.9 ^a,b	121.7 ^a	42.70
Colonic BCFA, µmol/g ⁴
Isobutyrate	2.3 ^a,b	3.3 ^b	1.2 ^a	1.6 ^a,b	0.45
Isovalerate	2.3 ^a	4.5 ^b	3.0 ^a,b	2.2 ^a	0.54
Valerate	2.4 ^a	4.9 ^b	0.9 ^a	1.3 ^a	0.55
Total BCFA	6.9 ^a	12.8 ^b	5.0 ^a	5.0 ^a	1.43

¹ Soluble fiber dextrin; ² Soluble corn fiber; ³ Pooled SEM; ⁴ Values are expressed on a dry matter basis; ^a,b,c Means in the same row with different superscript letters are different (P < 0.05).

4. Discussion

Rats consuming the SCF diet developed diarrhea soon after starting the treatment, but did not significantly decrease food intake or lose weight. Consumption of Pectin and SFD also resulted in looser stools by the end of the study, but not to the extent experienced by rats fed SCF. The % DM of the cecal and colon contents is reflective of the last day of experiment, which agrees with the fecal consistency observation. Weaver et al. [21] supplemented SCF and SFD to rats at 10% of the diet and found that they also developed loose stools. The test carbohydrates then were reduced to 5% dietary concentration and loose stools persisted, as was the case in the current study. Low-digestible carbohydrates such as SCF and SFD can result in tolerance issues such as diarrhea when consumed for a period of time [22,23,24].

Weaver et al. [21] also found that supplementation with SCF, SFD, and other novel fibers increased cecum weight compared to cellulose. In that study, supplementation of 4% SCF and SFD resulted in a cecum weight of 5.58 g, similar to what was found in the current study (cecal weight of 6.15 g and 6.72 g, respectively). Other research has demonstrated that ingestion of low-digestible carbohydrates resulted in increased cecum weights of rats [25,26,27,28]. The increased cecal weight likely is due to increased epithelial cell proliferation from the trophic effects of SCFA [29]. The major differences in organ weights were noted only for cecum and not for colon. This is probably due to the fact that the major site of fermentation for rodents is the cecum and not the colon as in humans. The decreased cecal pH is due to increased SCFA production at that site. Even though an increase in SCFA production was not always followed by a decrease in pH, this could potentially be a result of the production of lactic acid (not measured in this study) that would lead to pH change, but would not be accounted for in the total SCFA production.

Increased crypt depth as a result of dietary supplementation of low-digestible carbohydrates is a beneficial morphological effect. The crypts contain intestinal stem cells, the principal site of cell proliferation in the intestinal mucosa, and increased depth is associated with increased rate of turnover of intestinal mucosal cells [30,31]. Several studies have shown that pectin and other dietary fibers increase crypt depth throughout the intestinal tract [31,32,33]. However, pectin has been reported to simultaneously increase crypt depth and decrease villus height of the small intestine [32].

The increase in goblet cells per crypt may have a positive impact on gut health by increasing the thickness of the mucous layer of the large bowel. Other studies have reported increased goblet cell numbers in rats fed fermentable fibers including fructans and galactooligosaccharides [31,34,35,36,37]. Acidification of large intestinal contents is postulated to stimulate mucus synthesis and secretion [38] and could perhaps explain the increased numbers of goblet cells with the dietary treatments tested in this experiment. It has been suggested that acidic mucins protect against bacterial translocation because sulfated mucins (sulfomucins) in particular appear to be less degradable by bacterial glycosidases and host proteases [39]. Rats fed diets supplemented with low-digestible, inulin-type fructans have been shown to modulate mucins in the intestinal tract by increasing acidic mucins, especially the protective sulfomucins [31,36,40]. Alterations in the mucosal architecture and amounts of sulfomucins and sialomucins could have important effects on the gut mucosal barrier and health maintenance of the gut. Sulfomucins or sialomucins were found in both the cecal and colonic crypts. In the cecum, no differences among dietary treatments were observed. However, for the colonic crypts, diets supplemented with Pectin, SFD, and SCF had higher numbers of sulfomucins compared with Control.

Soluble corn fiber has been shown to affect microbial concentrations in vitro. Maathuis et al. [41] reported a 2-fold increase in Bifidobacterium spp. using SCF in a validated dynamic computer-controlled in vitro model of the human proximal large intestine (TIM-2), where soluble corn fiber was fermented for 36 h, with a feeding rate of 10 g of test substrate per 24 h period. A bifidogenic response also was found in a human in vivo study where healthy men were supplemented with 21 g/day of SCF for 21 days [42]. This dose of SCF was found to increase (P < 0.05) fecal concentrations of Bifidobacterium spp. compared with the non-fiber control (from 6.9 log10 cfu/g to 8.2 log10 cfu/g), but did not have any effect on Lactobacillus spp. or Escherichia coli populations. Pasman et al. [43] found that neither 30 nor 45 g/day of SFD increased Lactobacillus spp. in feces compared with a maltodextrin control in a human study. Neither carbohydrate affected microbiota concentrations in rat cecum, indicating potential differences in responses due to experimental design such as in vivo vs. in vitro model, species, dose of test substrates, and fermentation period.

The lack of difference between SFD and SCF as regards cecal SCFA compared to Control may be due to the increased cecal volume of rats consuming SFD and SCF, thus leading to a dilution effect for SCFA in cecal contents. Colonic SCFA concentrations were lower than those observed for cecal SCFA production. However, a similar pattern was observed, with Pectin treatment showing greater SCFA production. Small but similar amounts of colonic contents were found for all dietary treatments; thus, few differences among treatments were observed. The Control resulted in higher (P < 0.05) butyrate concentrations compared to SFD and SCF. The cecum is the main fermentative organ for the rat; therefore, a higher production of SCFA is to be expected at this site when compared to the colon.

Neither of the novel, low-digestible carbohydrates were butyrogenic in contrast to Control and Pectin treatments. Weaver et al. [21] found a similar response to SCF and SFD in cecal SCFA concentrations in rats. The supplemental SCF and SFD did not increase butyrate concentrations compared to a cellulose control when supplemented at 4% of the diet. Stewart et al. [44] found that supplementation of 12 g/day SFD and SCF to human subjects resulted in no differences in fecal SCFA concentrations compared with a maltodextrin control. Soluble corn fiber has been supplemented at 21 g/day to human subjects and, similar to results with rats, fecal butyrate concentrations were not increased compared with a control [42].

In general, colonic BCFA concentrations for Control rats were similar to those for rats fed SFD and SCF. However, as regards cecal BCFA concentrations, Control tended to result in higher concentrations than did SFD and SCF. Overall, for both cecal and colonic BCFA, Pectin had higher values than did the other dietary treatments. Pectin increases the viscosity of digesta, which could decrease crude protein digestion, resulting in higher quantities of amino acids reaching the cecum and colon where they would be fermented, thus producing BCFA [45,46].

Although this research provides valuable information on the fermentative behavior and on the potential beneficial effects of SFD and SCF in gut health, a limitation of this study is that the cecum is the major fermentative site in the rat, whereas in humans it is the colon. Furthermore, in this study these substrates were incorporated into a semi-purified diet, which differs from how these products may be consumed by humans. Also, results observed from SFD and SCF are dependent on the brand of each fiber source used herein; therefore, outcomes might vary when using different sources of SFD and SCF.

In summary, SFD and SCF both resulted in extensive fermentation in the cecum of rats. Dietary supplementation at the 5% level of the diet resulted in tolerance issues (loose stools) for the Pectin, SFD, and SCF treatments, but this did not affect food intake, body weight, or rate of weight gain. Diets containing SFD and SCF resulted in total cecal SCFA concentrations similar to those of Control diet. In general, Pectin resulted in higher concentrations of BCFA in cecal and colonic contents compared to SFD and SCF. Even though SFD and SCF did not result in increased butyrate concentrations, they nevertheless resulted in positive effects on cecal and colonic histomorphology.

5. Conclusions

In conclusion, SFD and SCF have the potential to beneficially impact large bowel morphology. Both of these low-digestible carbohydrates increased cecal weight, increased cecal and colonic crypt depths, and had a positive effect on goblet cells and mucin composition. Even though SFD and SCF were fermented in the hindgut of rats, they do not appear to be butyrogenic or bifidogenic in the rat. Future research is warranted to determine the optimal dietary supplementation level of SFD and SCF to minimize tolerance issues and to still provide beneficial effects on gut histomorphology important for maintenance of the gut health.

Conflict of Interest

The authors declare no conflict of interest.

References 1.

Cummings

J.H.

Roberfroid

M.B.

Andersson

Barth

Ferroluzzi

Ghoos

Gibney

Hermansen

James

W.P.T.

Korver

A new look at dietary carbohydrate: Chemistry, physiology and health

Eur. J. Clin. Nutr. 1997 51 417 423

10.1038/sj.ejcn.1600427

9234022

Anderson

J.W.

Baird

Davis

R.H.

Jr. Ferreri

Knudtson

Koraym

Waters

Williams

C.L.

Health benefits of dietary fiber

Nutr. Rev. 2009 67 188 205

10.1111/j.1753-4887.2009.00189.x

Murphy

Non-polyol low-digestible carbohydrates: Food application and functional benefits

Br. J. Nutr. 2001 85 S47 S53

10.1079/BJN2000261

Crittenden

R.G.

Playne

M.J.

Production, properties and applications of food-grade oligosaccharides

Trends Food Sci. Technol. 1996 7 353 361

10.1016/S0924-2244(96)10038-8

Roberfroid

Slavin

Nondigestible oligosaccharides

Crit. Rev. Food Sci. Nutr. 2000 40 461 480

10.1080/10408690091189239

Mussatto

S.I.

Mancilha

I.M.

Non-digestible oligosaccharides: A review

Carbohydr. Polym. 2007 68 587 597

10.1016/j.carbpol.2006.12.011

Ito

Satsukawa

Arai

Sugiyama

Sonoyama

Kiriyama

Morita

Soluble fiber viscosity affects both goblet cell number and small intestine mucin secretion in rats

J. Nutr. 2009 139 1640 1647

10.3945/jn.109.110171

Laurentin

Cardenas

Ruales

Perez

Tovar

Preparation of indigestible pyrodextrins from different starch sources

J. Agric. Food Chem. 2003 51 5510 5515

10.1021/jf0341518

Harrison

M.D.

Purdue

J.C.

Patton

P.A.

Hoffman

A.J.

Gaddy

J.M.

Chi-Li

Schanefelt

R.V.

Armentrout

R.W.

Schwenk

M.P.

Wicklund

R.A.

Food Products Comprising a Slowly Digestible or Digestion Resistant Carbohydrate Composition

U.S. Patent 2007/0172511 A1 14 December 2006 10.

Knapp

B.K.

Parsons

C.M.

Bauer

L.L.

Swanson

K.S.

Fahey

G.C.

Soluble fiber dextrins and pullulans vary in extent of hydrolytic digestion in vitro and in energy value and attenuate glycemic and insulinemic responses in dogs

J. Agric. Food Chem. 2010 58 11355 11363

10.1021/jf102397r

11.

Reeves

P.G.

Nielsen

F.H.

Fahey

G.C.

AIN-93 purified diets for laboratory rodents: Final report of the American Institute of Nutrition ad hoc writing committee on the reformulation of the AIN-76A rodent diet

J. Nutr. 1993 123 1939 1951

8229312

12. AOAC

Official methods of analysis

Association of Official Analytical Chemists 17th

AOAC International

Gaithersburg, MD, USA

2002 13.

Budde

E.F.

The determination of fat in baked biscuit type of dog foods

J. Assoc. Off. Agric. Chem. 1952 35 799 805 14. AACC

Approved methods

American Association of Cereal Chemists 8th

AACC International Press

St. Paul, MN, USA

1983 15.

Prosky

Asp

N.G.

Schwizer

T.F.

Devries

J.W.

Furda

Determination of insoluble and soluble dietary fiber in foods and food products: Collaborative study

J. Assoc. Off. Anal. Chem. 1992 75 360 367 16.

Erwin

E.S.

Marco

G.J.

Emery

E.M.

Volatile fatty acid analyses of blood and rumen fluid by gas chromatography

J. Dairy Sci. 1961 44 1768 1771

10.3168/jds.S0022-0302(61)89956-6

17.

Middelbos

I.S.

Godoy

M.R.

Fastinger

N.D.

Fahey

G.C.

A dose-response evaluation of spray-dried yeast cell wall supplementation of diets fed to adult dogs: Effects on nutrient digestibility, immune indices, and fecal microbial populations

J. Anim. Sci. 2007 85 3022 3032

10.2527/jas.2007-0079

18.

Morrison

Improved extraction of PCR-quality community DNA from digesta and fecal samples

Biotechniques 2004 36 808 812

15152600

19.

DePlancke

Vidal

Ganessunker

Donovan

S.M.

Mackie

R.I.

Gaskins

H.R.

Selective growth of mucolytic bacteria including Clostridium perfringens in a neonatal piglet model of total parenteral nutrition

Am. J. Clin. Nutr. 2002 76 1117 1125

12399288

20.

Filipe

M.I.

Mucins in the human gastrointestinal epithelium: A review

Investig. Cell Pathol. 1979 2 195 216 21.

Weaver

C.M.

Martin

B.R.

Story

J.A.

Hutchinson

Sanders

Novel fibers increase bone calcium content and strength beyond efficiency of large intestine fermentation

J. Agric. Food Chem. 2010 58 8952 8957

10.1021/jf904086d

22.

Livesey

Tolerance to low-digestible carbohydrates: A general view

Br. J. Nutr. 2001 85 S7 S16

10.1079/BJN2000257

23.

Marteau

Flourie

Tolerance to low-digestible carbohydrates: Symptomatology and methods

Br. J. Nutr. 2001 85 S17 S21

10.1079/BJN2000258

24.

Grabitske

H.A.

Slavin

J.L.

Low-digestible carbohydrates in practice

J. Am. Diet. Assoc. 2008 108 1677 1681

10.1016/j.jada.2008.07.010

25.

Levrat

M.A.

Remesy

Demigne

High propionic acid fermentation and mineral accumulation in the cecum of rats adapted to different levels of inulin

J. Nutr. 1991 121 1730 1737

1941180

26.

Campbell

J.M.

Fahey

G.C.

Wolf

B.W.

Selected indigestible oligosaccharides affect large bowel mass, cecal and fecal short-chain fatty acids, pH and microflora in rats

J. Nutr. 1997 127 130 136

9040556

27.

Z.X.

Gibson

P.R.

Muir

J.G.

Fielding

O’Dea

Arabinoxylan fiber from a by-product of wheat flour processing behaves physiologically like a soluble, fermentable fiber in the large bowel of rats

J. Nutr. 2000 130 1984 1990

10917912

28.

Kim

The water-soluble extract of chicory affects rat intestinal morphology similarly to other non-starch polysaccharides

Nutr. Res. 2002 22 1299 1307

10.1016/S0271-5317(02)00423-2

29.

Frankel

W.L.

Zhang

Singh

Klurfeld

D.M.

Don

Sakata

Modlin

Rombeau

J.L.

Mediation of the trophic effects of short-chain fatty acids on the rat jejunum and colon

Gastroenterology 1994 106 375 380

8299904

30.

Jin

Reynolds

L.P.

Redmer

D.A.

Caton

J.S.

Crenshaw

J.D.

Effects of dietary fiber on intestinal growth, cell proliferation, and morphology in growing pigs

J. Anim. Sci. 1994 72 2270 2278

7528192

31.

Kleessen

Hartmann

Blaut

Fructans in the diet cause alterations of intestinal mucosal architecture, released mucins and mucosa-associated bifidobacteria in gnotobiotic rats

Br. J. Nutr. 2003 89 597 606

10.1079/BJN2002827

32.

Jacobs

L.R.

Effects of dietary fiber on mucosal growth and cell proliferation in the small intestine of the rat: A comparison of oat bran, pectin, and guar with total fiber deprivation

Am. J. Clin. Nutr. 1983 37 954 960

6189387

33.

Lupton

J.R.

Kurtz

P.P.

Relationship of colonic luminal short-chain fatty acids and pH to in vivo cell proliferation in rats

J. Nutr. 1993 123 1522 1530

8395594

34.

Satchithanandam

Vargofcak-Apker

Calvert

R.J.

Leeds

A.R.

Cassidy

M.M.

Alteration of gastrointestinal mucin by fiber feeding in rats

J. Nutr. 1990 120 1179 1184

2170600

35.

Meslin

J.C.

Andrieux

Sakata

Beaumatin

Bensaada

Popot

Szylit

Durand

Effects of galacto-oligosaccharide and bacterial status on mucin distribution in mucosa and on large intestine fermentation in rats

Br. J. Nutr. 1993 69 903 912

10.1079/BJN19930090

36.

Fontaine

Meslin

J.C.

Lory

Andrieux

Intestinal mucin distribution in the germ-free rat and in the heteroxenic rat harbouring a human bacterial flora: Effect of inulin in the diet

Br. J. Nutr. 1996 75 881 892

10.1079/BJN19960194

37.

Schmidt-Wittig

Enss

M.L.

Coenen

Gartner

Hedrich

H.J.

Response of rat colonic mucosa to a high fiber diet

Ann. Nutr. Metab. 1996 40 343 350

10.1159/000177936

38.

Meslin

J.C.

Fontaine

Andrieux

Variation of mucin distribution in the rat intestine, caecum and colon: Effect of the bacterial flora

Comp. Biochem. Physiol. 1999 123 235 239 39.

DePlancke

Gaskins

H.R.

Microbial modulation of innate defense: Goblet cells and the intestinal mucus layer

Am. J. Clin. Nutr. 2001 73 S1131 S1141 40.

Delzenne

N.M.

Oligosaccharides: State of the art

Proc. Nutr. Soc. 2003 62 177 182

10.1079/PNS2002225

41.

Maathuis

Hoffman

Evans

Sanders

Venema

The effect of the undigested fraction of maize products on the activity and composition of the microbiota determined in a dynamic in vitro model of the human proximal large intestine

J. Am. Coll. Nutr. 2009 28 657 666

20516265

42.

Vester Boler

B.M.

Rossoni Serao

M.C.

Bauer

L.L.

Staeger

M.A.

Boilleau

T.W.

Swanson

K.S.

Fahey

G.C.

Digestive physiological outcomes related to polydextrose and soluble maize fibre consumption by healthy adult men

Br. J. Nutr. 2011 106 1864 1871

10.1017/S0007114511002388

43.

Pasman

Wils

Saniez

M.H.

Kardinaal

Long-term gastrointestinal tolerance of NUTRIOSE^® FB in healthy men

Eur. J. Clin. Nutr. 2006 60 1024 1034

10.1038/sj.ejcn.1602418

16482066

44.

Stewart

M.L.

Nikhanj

S.D.

Timm

D.A.

Thomas

Slavin

J.L.

Evaluation of the effect of four fibers on laxation, gastrointestinal tolerance and serum markers in healthy humans

Ann. Nutr. Metab. 2010 56 91 98

10.1159/000275962

45.

Brunsgaard

Eggum

B.O.

Sandstrom

Gastrointestinal growth in rats as influenced by indigestible polysaccharides and adaptation period

Comp. Biochem. Physiol. 1995 3 369 377 46.

Buraczewska

Swiech

Tusnio

Taciak

Ceregrzyn

Korczynski

The effect of pectin on amino acid digestibility and digesta viscosity, motility and morphology of the small intestine, and on N-balance and performance of young pigs

Livest. Sci. 2007 109 53 56

10.1016/j.livsci.2007.01.058