Hostname: page-component-586b7cd67f-g8jcs Total loading time: 0 Render date: 2024-11-23T00:23:07.916Z Has data issue: false hasContentIssue false

A comparative, randomised MRI study of the physiological and appetitive responses to gelling (alginate) and non-gelling nasogastric tube feeds in healthy men

Published online by Cambridge University Press:  07 February 2023

Abdulsalam I. Aliyu
Affiliation:
Department of Human Physiology, College of Medical Sciences, Gombe State University, Gombe, Nigeria The David Greenfield Human Physiology Unit, Division of Physiology, Pharmacology and Neuroscience, School of Life Sciences, Faculty of Medicine and Health Sciences, University of Nottingham, Nottingham, UK
Aline Nixon
Affiliation:
The David Greenfield Human Physiology Unit, Division of Physiology, Pharmacology and Neuroscience, School of Life Sciences, Faculty of Medicine and Health Sciences, University of Nottingham, Nottingham, UK
Caroline L. Hoad
Affiliation:
Sir Peter Mansfield Imaging Centre, School of Physics and Astronomy, University of Nottingham, Nottingham, UK NIHR Nottingham Biomedical Research Centre at Nottingham University Hospitals NHS Trust and University of Nottingham, Nottingham, UK
Luca Marciani
Affiliation:
Sir Peter Mansfield Imaging Centre, School of Physics and Astronomy, University of Nottingham, Nottingham, UK NIHR Nottingham Biomedical Research Centre at Nottingham University Hospitals NHS Trust and University of Nottingham, Nottingham, UK Nottingham Digestive Diseases Centre, Translational Medical Sciences, School of Medicine, University of Nottingham, Nottingham, UK
Maura Corsetti
Affiliation:
NIHR Nottingham Biomedical Research Centre at Nottingham University Hospitals NHS Trust and University of Nottingham, Nottingham, UK Nottingham Digestive Diseases Centre, Translational Medical Sciences, School of Medicine, University of Nottingham, Nottingham, UK
Guruprasad P. Aithal
Affiliation:
NIHR Nottingham Biomedical Research Centre at Nottingham University Hospitals NHS Trust and University of Nottingham, Nottingham, UK Nottingham Digestive Diseases Centre, Translational Medical Sciences, School of Medicine, University of Nottingham, Nottingham, UK
Sally M. Cordon
Affiliation:
The David Greenfield Human Physiology Unit, Division of Physiology, Pharmacology and Neuroscience, School of Life Sciences, Faculty of Medicine and Health Sciences, University of Nottingham, Nottingham, UK
Ian A. Macdonald
Affiliation:
The David Greenfield Human Physiology Unit, Division of Physiology, Pharmacology and Neuroscience, School of Life Sciences, Faculty of Medicine and Health Sciences, University of Nottingham, Nottingham, UK NIHR Nottingham Biomedical Research Centre at Nottingham University Hospitals NHS Trust and University of Nottingham, Nottingham, UK Nestlé Institute of Health Sciences, Nestlé Research, Société des Produits Nestlé S.A, Lausanne, Switzerland
Maha H. Alhussain
Affiliation:
Department of Food Science and Nutrition, King Saud University, Riyadh, Saudi Arabia
Hiroaki Inoue
Affiliation:
Global Planning Group, Medical Solutions Vehicle, KANEKA CORPORATION, Osaka, Japan
Masahiko Yamada
Affiliation:
Regenerative Medicine and Cell Therapy Laboratories, KANEKA CORPORATION, Kobe, Japan
Moira A. Taylor*
Affiliation:
The David Greenfield Human Physiology Unit, Division of Physiology, Pharmacology and Neuroscience, School of Life Sciences, Faculty of Medicine and Health Sciences, University of Nottingham, Nottingham, UK NIHR Nottingham Biomedical Research Centre at Nottingham University Hospitals NHS Trust and University of Nottingham, Nottingham, UK
*
*Corresponding author: Moira A. Taylor, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Inclusion in nasogastric tube feeds (NGTF) of acid-sensitive, seaweed-derived alginate, expected to form a reversible gel in the stomach, may create a more normal intragastric state and modified gastrointestinal responses. This may ameliorate NGTF-associated risk of diarrhoea, upper gastrointestinal symptoms and appetite suppression. In a randomised, crossover, comparison study, undertaken in twelve healthy males, an alginate-containing feed (F + ALG) or one that was alginate-free (F-ALG) (300 ml) was given over 1 h with a 7–14-d washout period between treatments. Baseline and for 4-h post-feed initiation, MRI measurements were made to establish small bowel water content (SBWC), gastric contents volume (GCV) and appearance, and superior mesenteric artery blood flux. Blood glucose and gut peptides were measured. Subjective appetite and upper gastrointestinal symptoms scores were obtained. Ad libitum pasta consumption 3-h post-feeding was measured. F + ALG exhibited a gastric appearance consistent with gelling surrounded by a freely mobile water halo. Significant main effects of feed were seen for SBWC (P = 0·03) and peptide YY (PYY) (P = 0·004) which were attributed to generally higher values for SBWC with F + ALG (max difference between adjusted means 72 ml at 210 min) and generally lower values for PYY with F + ALG. GCV showed a faster reduction with F + ALG, less between-participant variation and a feed-by-time interaction (P = 0·04). Feed-by-time interactions were also seen with glucagon-like-peptide 1 (GLP-1) (P = 0·02) and glucose-dependent insulinotropic polypeptide (GIP) (P = 0·002), both showing a blunted response with F + ALG. Apparent intragastric gelling with F + ALG and subsequent differences in gastrointestinal and endocrine responses have been demonstrated between an alginate-containing and alginate-free feed.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© University of Nottingham, 2023. Published by Cambridge University Press on behalf of The Nutrition Society

An estimated 25 % of adults admitted to hospital in the UK are undernourished(1) and are commonly treated by nasogastric tube feeding (NGTF)(1). NGTF-associated diarrhoea, however, occurs in 2 % to 63 % of cases; the range being attributed to such factors as method of measurement and definition of diarrhoea(Reference Whelan, Judd and Taylor2Reference Cara, Beauchesne and Wallace7). Negative clinical consequences included compromised nutrient, electrolyte and fluid absorption, and increased fecal incontinence predisposing to loss of skin integrity and pressure sore infection(Reference Tatsumi8Reference Hodgkinson, Evans and Wood10). Nausea, vomiting and upper gastrointestinal symptoms are also increased during NGTF, increasing the risk of aspiration pneumonia and death(Reference Blumenstein, Shastri and Stein6,Reference Cara, Beauchesne and Wallace7,Reference Studer, Räber and Ott11) . NGTF have also been implicated in suppressing appetite. These complications may lead to suboptimal feeding rates or withdrawal of the feed(Reference Tatsumi8).

Disruption to the normal gastrointestinal response to feeding may occur when feeding a liquid, via a tube, directly into the stomach. The oral and oesophageal response are bypassed, and gastric emptying rates of liquids, meals of mixed consistency, and solids into the small intestine differ(Reference Achour, Méance and Briend12Reference Horowitz, Edelbroek and Wishart14). This may contribute to NGTF complications with disruption of the complex central and peripheral neural, endocrine and microbial regulatory systems controlling not only gastric emptying but also freely mobile small bowel water content (SBWC)(Reference Eisenberg4Reference Blumenstein, Shastri and Stein6,Reference Achour, Méance and Briend12Reference Reis, Fruchtenicht and Loss16) . Whilst products of digestion and up to 90 % of the ingested and secreted water are usually absorbed within the small intestine, abnormal levels of small bowel water have been noted in diseases where diarrhoea is present(Reference Marciani, Cox and Hoad17Reference Lam, Sanders and Lanyon19), and the rate of water delivery to the colon has been associated with fecal consistency by some(Reference Debongnie and Phillips20), but not others(Reference Hammer and Phillips21). Furthermore, altered colonic water absorption has been identified with NGTF(Reference Bowling5). A liquid diet may increase the risk of upper gastrointestinal symptoms(Reference Wu, Rayner and Chuah22Reference Marik and Zaloga28).

Alginates, polysaccharides derived from the cell walls of brown seaweed(Reference Stokke, Draget and Smidsrød29Reference Nishitani, Sato and Fukuyama31), are liquid in neutral and alkali conditions and, hence, can be intragastrically fed via a fine bore tube but would be expected to form a reversible gel in the acid environment of the stomach(Reference Inoue, Kawashima and Hamada32Reference Ishikawa, Matsumura and Tomitsuka34). Formation of a gel may induce an intragastric state which is comparable to that following consumption of a semi-solid or solid meal and may reduce NGTF complications such as reflux and diarrhoea and thus is used in Japan(Reference Inoue, Kawashima and Hamada32Reference Ishikawa, Matsumura and Tomitsuka34). Prior to studying the use of gelling NGTF in patient groups, it is important first to demonstrate in healthy participants, a difference in gastrointestinal response, when compared with a non-gelling NGTF.

The purpose of this study was thus to test the hypothesis, in healthy participants, that acute exposure to an NGTF that forms a gel intragastrically results in different gastrointestinal responses compared with a non-gelling feed. Using MRI, the gastric appearance, the liquid and semi-liquid gastric contents volume (GCV) and SBWC (primary outcome) were measured when feeding a gelling and non-gelling feed. SBWC was defined as freely mobile water with a bright-white appearance with MRI. Post-feeding blood glucose and serum insulin profiles, plasma gut hormone profiles, superior mesenteric artery (SMA) blood flux, and measures of upper gastrointestinal symptoms and appetitive response were obtained to identify potential mechanisms and clinical consequences. The feeds that were compared were a sodium alginate-containing feed that was expected to gel in the stomach and a non-gelling feed of similar energy and macronutrient composition.

Materials and methods

Participants and ethics

This study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving human subjects/patients were approved by the Faculty of Medicine and Health Sciences Research Ethics Committee of the University of Nottingham: ref: 97–1809. The study was registered with clinicaltrials.gov (ref: NCT04113200) (URL- www.clinicaltrials.gov). Written informed consent was obtained from all participants both before screening and prior to the main study. Recruitment and the main study intervention were conducted in the David Greenfield Human Physiology Laboratory and the Sir Peter Mansfield Imaging Centre of the University of Nottingham, UK. Recruitment was via posters displayed at the University of Nottingham between December 2018 and March 2020, and participants were enrolled by the lead researcher (AIA). Inclusion criteria were healthy males aged 18–45 years, with a BMI of 18·5–24·5 kg/m2, or a BMI of 24·5–26 kg/m2 and a waist circumference of less than 94 cm, and the ability to provide informed consent. Exclusion criteria were as follows: a history of acute illness lasting more than 1 week in the 6 weeks prior to starting the trial; a history of gastrointestinal disorders, including gastro-oesophageal reflux disease, irritable bowel syndrome or active peptic ulcer disease; taking medication for gastrointestinal disorders (including acid suppressants, antispasmodics and antidepressants) or medication for diabetes; a history of substance abuse in the last 6 months; previous surgery to the gastrointestinal or biliary system; symptoms of clinical depression defined by a score of > 10 on the Beck Depression Inventory(Reference Metcalfe and Goldman35) and those with characteristics of eating disorder defined by a score of > 20 on the Eating Attitude Test – EAT-26(Reference Garner, Olmsted and Bohr36); and any factors that precluded safe MRI use. Volunteers were also excluded if they had allergies or an intolerance to any of the ingredients contained in the two NGTF or the cheese and tomato pasta meal, or if they had been involved in another trial less than 3 months prior to this study.

Study design

A comparative, randomised study was undertaken with a crossover design. Each participant attended a screening visit (1 h), and then for each of the two arms of the study, a pre-study visit (30 min), an approximately 6-h study day visit (when 300 ml of nasogastric feed was administered over 1 h, with follow-up measurements over the subsequent 3 h), and a post-study day visit (30 min), 3 d later. The intervention feed, Mermed One, TERUMO CORPORATION, Japan (invented by KANEKA CORPORATION) contained sodium alginate as the main source of gelling fibre with polydextrose (a slowly fermented, non-gelling, synthetic glucose polymer)(Reference do Carmo, Walker and Novello37) and cellulose (a glucose polymer with a high degree of polymerisation) (F + ALG). The comparator feed (without alginate) was Nutricomp Soy Fibre, B. Braun, Melsungen, Germany, and contained inulin (a fermentable fructan) and wheat dextrin (a fermentable, resistant starch) as sources of fibre (F-ALG). Table 1 provides a summary of the composition of the feeds, and more detail is provided in Supplementary Item 1.

Table 1. Composition of the two feeds per 300 ml

F + ALG, alginate-containing feed; F–ALG, alginate-free feed

Randomisation and blinding

Participants were randomly assigned with equal probability to receive either feed on the first study day visit, based on a computer-generated random code (randomisation.com) by the research nurse. The alternate feed was then provided on the second visit. The lead researcher, MRI operator, participant and laboratory technician undertaking the blood analysis were blind to the feed given. The research nurse who set up the NGTF and collected the blood samples was aware of treatment sequence, for safety reasons, but had no subsequent access to data. Participants were blind to the feed provided.

Pre-study

For 4 d prior to the study day visit, participants were instructed to: follow two repetitions of a standardised 2-d menu based on a self-completed 3-d food record that had been adjusted to provide a comparable percentage energy from macronutrients and relative fibre content to the NGTF (based on the mean content of the two feeds); refrain from strenuous physical activity; and not consume alcohol and caffeine. For the 3 d prior to the study visit, participants were instructed to collect the first stool of the day (using the kit provided) and for every stool to complete the King’s Stool Chart(Reference Whelan, Judd and Taylor38) and photograph each stool using the disposable camera provided (results not reported in this paper).

Study day visit protocol

Participants attended the MRI centre, at the Sir Peter Mansfield Imaging Centre, at 8 am having fasted overnight. Following weighing, an intravenous cannula was inserted in a retrograde direction into a dorsal foot vein for the collection of blood samples. A small intradermal injection of 1 % lidocaine was administered at the site of insertion. A 3-way tap and primary giving set were attached to the cannula and an intravenous infusion of 0·9 % saline delivered slowly to keep the vein open throughout the study visit. Participants were then intubated with a 120-cm-length 8-French gauge (FG) fine bore nasogastric tube (NGP18/120L, HMC PREMEDICAL S.p.A. Italy), inserted through an anesthetised nostril as described previously(Reference Bowling, Cliff and Wright39). Fifty millilitres of water were consumed during placement which was confirmed as correct by aspiration of the stomach contents and ensuring a pH of ≤ 5·5 on CE-marked pH indicator strip (GBUK Group LtdUK). The length marking on the nasogastric tube was replicated on the second study visit. Having removed the guide wire participants entered the 3T Achieva MRI scanner (Philips Medical Systems, Best) and lay flat on the bed where they remained for the subsequent 4 h. The cannulated foot was placed in a hot air box (50–55°C) to provide arterialised venous blood(Reference Liu, Moberg and Kollind40,Reference Seaquist41) . The scanning bed was removed from the scanner between scans.

The first MRI scan (20 min including set-up) was undertaken to determine baseline values for SBWC, SMA blood flux(Reference Totman, Marciani and Foley42) and GCV. Two baseline blood samples were obtained with a 5-min interval between them. All blood samples over the study were drawn using the three-way tap, and the first 2 ml was discarded. Prior to each blood sample, participants completed paper-based 100-mm visual analogue scale (VAS) relating to subjective appetite sensations and upper gastrointestinal symptoms.

The feed was then delivered at room temperature, via the tube, using a bespoke, MRI compatible, pressure bag system allowing constant adjustment of the drip rate so that a total of 300 ml of feed was delivered over 1 h (+ or – 6 min).

During the 1 h of feeding and subsequent 3 h, MRI scans were undertaken approximately every half-hour; blood sampling continued at 10 min (glucose) and 20 min (insulin and gut hormones) intervals and VAS (upper gastrointestinal symptoms and appetite scores) were completed at 30-min intervals, prior to blood sampling.

Four hours from the start of feeding, participants left the scanner, the intravenous cannula and nasogastric tube were removed, and they were offered a cheese, tomato and pasta meal (served at 82°C) which they were instructed to eat, with no time restriction, until they felt comfortably full as described previously(Reference Alhussain, Macdonald and Taylor43). When approximately one-quarter of the bowl of food was left, it was replaced with a full bowl to avoid prompting meal termination (‘Bottomless bowl technique’)(Reference Wansink, Painter and North44). Participants drank 200 ml of water whilst consuming the pasta meal. The full amount prepared contained about 11 000 kJ (2630 kcal) of energy, 300 g of carbohydrate (45·6 %), 82 g of protein (12·5 %) and 122 g of fat (41·8 %) and was divided into three portions. Appetite and upper gastrointestinal symptom scores using VAS were completed immediately before the meal and immediately afterwards, and the duration of eating was recorded.

Participants left the unit having been instructed to follow their standardised food menu for the remainder of that day and the subsequent 2 d and to record compliance on the form provided. A fecal collection kit was provided for sampling of the first available fecal sample on the day of the study, and on each of the next 2 d. The participants were required to record all other stools using the adapted King’s Stool Chart(Reference Whelan, Judd and Taylor38) and a reusable camera (results not reported in this paper). They were instructed to complete the upper gastrointestinal symptom scores at the end of the day, just before going to bed.

Following a 7–14-d washout period consuming their habitual diet, participants repeated the previously stated protocol with the opposite feed delivered during the study visit.

A repeat trial was conducted in a participant whose blood samples could not be taken during the MRI scans due to the cannula failing, having moved from the vein into adjacent tissue. The same protocol was repeated, but without scans, in the Sir David Greenfield Human Physiology Unit, University of Nottingham, having obtained further consent and undertaken a repeat screening.

Procedures

MRI measurements

The GCV measurements were acquired using two single-shot turbo spin echo (TSE) sequences with two different TE (echo time), one with 60 min and the other 300 min, each of which lasted 22 and 36 s, respectively. Each had twenty contiguous slices, which were 10 mm thick and were acquired with in-plane resolution of 1·5 mm x 1·88 mm with no gap between slices but were reconstructed to 1 × 1 pixel size. The scans were acquired in expiration breath hold. The 36-s breath hold was split into two for convenience of the participant. This imaging sequence produced a good contrast between the stomach contents and other abdominal organs.

SBWC was acquired using a previously described and validated technique applying a fat-saturated coronal single-shot turbo spin echo sequence acquiring twenty contiguous coronal slices with reconstructed in-plane resolution of 0·78 mm × 0·78 mm and slice thickness of 7 mm with no gaps between slices, TE = 400 min and TR 1159 min. Data were collected during an expiration breath hold of 23 s.

Axial, coronal and sagittal balanced turbo gradient echo bright blood localiser scans were used to position the flow measurement plane perpendicular to the SMA. The SMA blood flux was measured using a 2D gradient echo cine phase contrast MRI scan with TE = 3·3 ms, TR = 7·5 ms and flip angle 25°. Reconstructed in-plane resolution was 1·17 mm × 1·17 mm and slice thickness 6 mm, velocity encoding 140 cm/s with flow encoding through plane. This was acquired in a 14-s breath hold.

Gastric image analysis was performed, blind to the feed, using MIPAV (Medical Imaging Processing, Analysis and Visualization) software v9.0.0 (Reference McAuliffe, Lalonde and McGarry45) which is freely available. GCV was measured by manually tracing the region of interest around the liquid and solid contents within the stomach on each slice. The GCV at each time point was calculated by multiplying the surface area of the gastric content measured per slice with the thickness of the slice and then summed up to produce the total GCV in ml, and intragastric air was excluded from the region of interest.

The SBWC images were analysed using validated in-house custom written software (IDL 6·4, Research Systems Inc.)(Reference Marciani, Cox and Hoad17,Reference Hoad, Marciani and Foley46) . Briefly, regions of interest were drawn around the small bowel, excluding the gall bladder, bladder, colon and stomach as well as blood vessels. Voxels with an intensity above a threshold, which was determined from that person’s cerebrospinal fluid intensity, were identified as free small bowel water. The sum of these voxel volumes within the small bowel regions of interest provided an estimate of total SBWC.

The SMA blood flux data were analysed using validated manufacturer’s software (Philips QFlow software) developed to assess the blood flow in different areas of human body(Reference Totman, Marciani and Foley42,Reference Hoad, Marciani and Foley46Reference Kozerke, Botnar and Our48) . A line was drawn approximately around the SMA vessel on one image and the software, then automatically reduced the region of interest to the size and shape of the vessel and tracked it over the cardiac cycle. The software then automatically calculated the SMA blood flux (ml/s).

Characterisation of intragastric gel content

T2-weighted gastric images with the longer echo time (TE 300) were used to visualise and characterise the gastric contents. Images acquired were inspected for their appearance by two independent researchers with extensive experience of analysing gastric images. The images were classified into ‘consistent with gel’ and consistent with ‘non-gel’. Images were identified as having a gel-like appearance when they displayed a heterogenous intragastric dark material with a white ring around it consistent with gel formation on T2-weighted MRI imaging or non-gel with a homogenous intragastric bright material (Fig. 1). These were distinguished from air which appears uniformly darker than any aspect of the image. All slices across the time points were examined and reported. The randomisation code was then broken.

Fig. 1. The flow of the participants from screening to final data analysis. All blood samples analysed were for seven participants except for GLP-1 (n 6) where one participant was excluded from analysis due to abnormally low levels which were undetectable. GLP-1, glucagon-like-peptide 1.

Blood sample collection technique, processing and analysis

For blood glucose, 0·5 ml of whole blood (WB) was collected into cold fluoride/citrate tubes, mixed gently, kept on ice and analysed within 2 h using YSI 2300 STAT PLUS (YSI Inc. Yellow Springs).

The remaining blood was gently mixed in tubes containing the appropriate preservative, centrifuged (3000 g 4°C for 10 min) and plasma/serum aspirated, aliquoted and frozen at minus 80°C as appropriate for the intended analyses. All samples were kept on ice throughout processing, except for serum samples which were kept at room temperature for the first 15 min to enable the blood to clot. Preservatives used were as follows: active glucagon-like-peptide 1 (GLP-1) required EDTA tubes with added DPP IV inhibitor (10 µl/ml WB), and total peptide YY (PYY) and total ghrelin both required EDTA tubes with added aprotinin (500 Kallikrein Inactivator units/ml WB). Insulin and total glucose-dependent insulinotropic polypeptide (GIP) required serum, and plain serum-separator tubes were used.

Analytical techniques were either RIA (PYY, ghrelin, and insulin) or ELISA (active GLP-1 and GIP) as used previously(Reference Alhussain, Macdonald and Taylor43,Reference Khalaf, Hoad and Menys49Reference Alyami, Whitehouse and Yakubov51) . All kits were Merck-Millipore (EMD Millipore). For these study samples, the mean intra-assay and inter-assay CV for total ghrelin was 4·9 % and 7·7 %; PYY was 4·2 % and 9·7 %; insulin was 3·6 % and 3·8 %; active GLP-1 was 4·6 % and 9·0 % and total GIP was 2·4 % and 4·4 %, respectively.

VAS scores for appetite and upper gastrointestinal symptom scores

The paper-based VAS was made up of a 100 mm line anchored at each end with positive and negative extremes for each of the appetite variables (hunger, fullness, satisfaction, desire to eat and prospective food consumption). Without reference to previous ratings, participants instructed the research nurse to mark a vertical line across the horizontal 100 mm line, and the metric value (mm) was measured from the 0 mm (on the left) to the vertical mark.

The characterisation of the upper gastrointestinal symptoms scores was reported on a VAS of 0–100 mm, with absence of symptoms = 0 and very severe symptoms = 100 at each end, in conjunction with a pictorial representation of symptoms and verbal description(Reference Tack, Carbone and Holvoet52). The symptoms assessed were as follows: (i) how hard it was to finish a normal meal; (ii) feeling of food lying heavily in the stomach; (iii) feeling of bloating in the stomach; (iv) pain suffered in the stomach area; (v) burning feeling in the stomach area; (vi) feeling of nausea; (vii) feeling of troublesome burping; (viii) burning feeling behind breastbone; (ix) feeling of acid taste in mouth; and (x) unpleasant movement of material upwards from stomach area.

Sample size, data analysis and statistical analysis

The power calculation was based on the work of Marciani et al. in 2010(Reference Marciani, Cox and Hoad17) who demonstrated that in eleven healthy volunteers given glucose, the mean postprandial SBWC at 40 min was 47 ml with a sd of 15 ml. We estimated that with statistical power at the level of 0·8, the number of participants required to detect a difference in the mean response of matched pairs of 15 ml, with a crossover design was 10, based on a two-sided α of 0·05.

SPSS software version 27 (IBM SPSS statistics) and GraphPad Prism 9.0.0. (GraphPad Software Inc.) were used for statistical analysis and drawing graphs, respectively.

All results presented are mean and standard deviation unless otherwise stated. Normality of data was tested using Shapiro–Wilks test. Appropriate parametric tests were carried out on normally distributed data and equivalent non-parametric test when data were not normally distributed (i.e. upper gastrointestinal symptom scores).

For pH of gastric aspirate on insertion of the nasogastric tube, SBWC, GCV, SMA blood flux, blood glucose, serum insulin and gut hormones, baseline values were compared using the t test, to ensure that there was no carry over or sequence effect. Then change from baseline was calculated for each data point. These data were then graphically presented and used in subsequent analysis. The nature of the response, considering both magnitude and shape of each of the treatment curves, was compared using a two-way repeated-measures ANOVA (having ensured the conditions required for an ANOVA had not been violated), where factor 1 = feed type (F + ALG and F–ALG) and factor 2 = time point at which measurements were made. When an interaction was identified, simple effects of feed were explored by comparing the feeds at each time point applying a Bonferroni correction for multiple testing. When no statistically significant interaction was identified, the main effects of feed and time (applying Bonferroni corrections) were considered for statistical significance. Missing MRI values were derived by using the values either side of the missing value to calculate the ratio between the participant and the mean of the others and then applying this ratio to the mean value for the others at the missing timepoint'.

For subjective appetite scores, and the upper gastrointestinal symptom scores, the net incremental AUC (nAUC) was calculated by applying the trapezoid rule to data from which the baseline had been subtracted. The positive or negative sign of the number was preserved; hence, the AUC was considered to be net.

Energy consumed in the pasta meal, nAUC for subjective appetite scores, nAUC for the upper gastrointestinal symptom scores and end of the day upper gastrointestinal symptom scores were compared using t tests.

Differences were considered significant at P < 0·05 for all statistical tests.

Results

Baseline characteristics of participants

Thirteen participants meeting the inclusion criteria were randomised. One participant was withdrawn after 60 min, during the first arm of the study, due to vomiting. Of the remaining twelve participants, two were excluded subsequently from the analysis due to non-compliance with study procedure (n 1) or an abnormally high baseline GCV (n 1) (Fig. 2). The baseline characteristics of the remaining ten participants are presented in Table 2. In four participants, not all time points were available for blood samples. One participant voluntarily undertook a repeat trial, with blood collection, outside the MRI scanner. Blood sample analysis was thus undertaken on seven participants, except for GLP-1 as one participant was excluded due to an abnormally low, undetectable level. Results for six participants for GLP-1 were thus presented.

Fig. 2. T2-weighted (TE = 300) axial images of the stomach showing characteristics of intragastric contents for the two feeds (F + ALG and F-ALG) 90 min after the commencement of feeding in one of the participants. The green arrows indicate the gastric contents. The freely mobile water appears as a bright white halo around a darker intragastric feed region which has a gel-like appearance, with F + ALG (left-hand image). The greyer appearance of the homogenous feed can be seen with F-ALG with no freely mobile water visualised as a bright white signal (right-hand image). F + ALG, alginate-containing feed; F–ALG, alginate-free feed; TE, echo time.

Table 2. Baseline characteristics of participants whose data were analysed (n 10)

BDI, Beck’s Depression Inventory; EAT, Eating Attitudes Test.

Gastric pH measured on insertion of the nasogastric tube was similar for the participants (n 10) before F + ALG and F-ALG (respectively, 3·5 ± 1·0 v. 3·4 ± 1·3, P = 0·83).

Gastric contents characteristics

The T2-weighted images taken after the commencement of feeding revealed two distinct features in the stomach from 90 min until 120 min, one darker and non-homogenous, consistent with gel formation surrounded by a bright-white ring consistent with freely mobile water (F + ALG) and the other greyer and homogenously bright (F-ALG) consistent with a liquid state. Figure 1 shows an example of the MRI images seen.

Small bowel water content volumes

Changes from baseline in SBWC are shown in Fig. 3(a). The values at baseline were similar (F + ALG = 119 ± 2 ml and F-ALG = 123 ± 3 ml; P = 0·65) and began to decrease on the commencement of feeding, reaching the lowest levels at 90 min F + ALG (–104 ± 86 ml) and F-ALG (–97 ± 98 ml), representing a decrease of 68 ± 28 % and 68 ± 30 % relative to baseline, respectively. The level then rose in both feeds, although the mean for the group for SBWC in the F-ALG remained below the baseline level at the end of the 3-h post-feeding period with the group mean for F + ALG above baseline values (Fig. 3(a)). There was, however, no significant feed-by-time interaction for the SBWC measurements (P = 0·12), although there were significant main effects of feed (P = 0·03) and time (P < 0·001) (data adjusted for baseline).

Fig. 3. Change from baseline for small bowel water contents volume (SBWC) (a), gastric contents volume (GCV) (b) and superior mesenteric artery (SMA) blood flux (c) through 1 h of feeding and 3-h post-feeding (mean ± sem) in F + ALG and F-ALG (n 10). (a): For SBWC volume, no significant feed-by-time interaction was seen (P = 0·120). There was a statistically significant main effect for feed (P = 0·03) with the SBWC volume being greater for F + ALG compared with F-ALG and a significant main effect for time (P < 0·001). (b) For GCV, there was a statistically significant feed-by-time interaction (P = 0·04). Pairwise comparison between feeds revealed no significant difference in GCV for each of the time points (P > 0·05). (c): For SMA blood flux, there was no significant feed-by-time interaction (P = 0·22) or main effect of feed (P = 0·34), although there was a main effect of time (P < 0·001). F + ALG, alginate-containing feed; F–ALG, alginate-free feed.

A representative image of the SBWC measurements in a single participant taken at 210-min post-feeding period demonstrates a larger irregular bright region in both flanks (Fig. 4(a)) for F + ALG which is consistent with higher SBWC volume and a smaller irregular bright area in both flanks (Fig. 4(b)) for F-ALG consistent with a smaller SBWC volume.

Fig. 4. Coronal images of the abdomen in a single representative participant with the freely mobile water in the small bowel showing as bright white areas for F + ALG (a) and F-ALG (b), taken at 210 min after the commencement of feeding. More freely mobile water is evident with more bright white areas in A with F + ALG. (F + ALG, alginate-containing feed; F–ALG, alginate-free feed).

Gastric contents volumes

Changes from baseline for GCV are shown in Fig. 3(b). The values at baseline were similar (F + ALG = 55 ± 7 ml and F-ALG = 68 ± 7 ml; P = 0·24) and then increased after feeding commenced, reaching absolute values of 248 ± 14 ml for F + ALG and 256 ± 9 ml for F-ALG at 60 min. Numerically, GCV then reduced more rapidly with the alginate-containing feed at each time point. Values had returned to baseline 3 h after feeding ceased in both groups. Less variation was seen in GCV profile between participants for F + ALG compared with F-ALG as indicated by the difference in magnitude of the error bars.

A significant feed-by-time interaction was seen (P = 0·04). Pairwise comparison, between feeds, at each time point identified no significant simple effects of feed.

Superior mesenteric artery blood flux

Changes from baseline for SMA blood flux are shown in Fig. 3(c). The values at baseline were similar (F + ALG = 7·6 ± 0·6 ml/s and F-ALG = 8·5 ± 0·7 ml/s) (P = 0·24) and then increased once feeding commenced with a numerically earlier and higher peak with F-ALG (at 30 min, absolute values: 18·3 ± 6·8 ml/s) compared with F + ALG (at 60 min; absolute values: 14·4 ± 4·9 ml/s). Values had then returned to baseline by 180 min approximately.

No significant feed-by-time interaction (P = 0·22) or main effect of feed (P = 0·11) was seen, although there was a main effect of time (P < 0·001).

Blood glucose

Blood glucose values at baseline, after an overnight fasting, were similar (F + ALG = 4·3 ± 0·3 mmol/l and F-ALG = 4·2 ± 0·3 mmol/l; P = 0·23). Numerically, after an initial drop from baseline at 10 min, an increase was seen in both feeds during the feeding period, resulting in absolute peaks at 60 min (F + ALG = 6·1 ± 0·5 mmol/l and F-ALG = 5·9 ± 0·4 mmol/l) followed by a gradual decline to baseline after 3 h (online Supplementary Item 3).

No significant feed-by-time interaction (P = 0·64) or main effect of feed (P = 0·97) was seen, whilst there was a significant main effect of time (P < 0·001).

Serum insulin

Changes from baseline are shown for serum insulin in Fig. 5. Serum insulin levels at baseline were similar (F + ALG = 7·5 ± 1·2 mIU/l and F-ALG = 6·5 ± 0·7 mIU/l; P = 0·31). Serum insulin levels then rose after feeding commenced, reaching peak levels at 60 min in F + ALG (41·8 ± 22·7 mIU/l) and F-ALG (47·9 ± 14·1 mIU/l), and then numerically, returning to baseline by 160 min in F + ALG and 200 min in F-ALG feeds.

Fig. 5. Change from baseline for serum insulin through 1 h of feeding and 3-h post-feeding (mean ± sem) in F + ALG and F-ALG feeds (n 7). No significant feed-by-time interaction (P = 0·69) was seen, but there was a significant main effect of feed (P = 0·01) and time (P < 0·001). (F + ALG, alginate-containing feed; F–ALG, alginate-free feed).

No significant feed-by-time interaction was seen for serum insulin levels (P = 0·68), although significant main effects of feed (P = 0·01) and time (P < 0·001) were observed.

Serum total glucose-dependent insulinotropic polypeptide

Changes from baseline for serum total GIP are shown in Fig. 6(a). The values at baseline were similar (F + ALG = 35·9 ± 20·2 pg/ml and F-ALG = 37·2 ± 19·3 pg/ml; P = 0·914) and then increased once feeding commenced, reaching absolute peak values at 1 h (F + ALG = 323·0 ± 91·6 pg/ml and F-ALG = 381·6 ± 150·0 pg/ml). Numerically, F + ALG then declined more rapidly, and with both feeds, levels approached the baseline by 240 min.

Fig. 6. Change from baseline for (a) serum total GIP (n 7), (b) plasma-active GLP-1 (n 6), (c) plasma PYY (n 7) and (d) plasma ghrelin (n 7), through 1 h of feeding and 3-h post-feeding (mean ± sem) for F + ALG and F-ALG. (a) (serum total GIP): There was a significant feed-by-time interaction (P = 0·002). Pairwise comparison showed significantly lower levels with F + ALG than with F-ALG at 100 min (P = 0·04), 120 min (P = 0·01), 140 min (P = 0·03), 160 min (P = 0·03) and 180 min (P = 0·03). (b) (plasma-active GLP-1): There was a significant feed-by-time interaction (P = 0·02). Pairwise comparison showed significantly lower levels with F + ALG than with F-ALG at 60 min (P = 0·03), 100 min (P = 0·001), 120 min (P = 0·002) and 180 min (P = 0·003). (c) (plasma PYY): No feed-by-time interaction (P = 0·44) was seen, but a main effect of feed (P = 0·004) was observed with no significant main effect of time (P = 0·10). (d) (plasma ghrelin): There was a tendency for a feed-by-time interaction observed (P = 0·07), no significant effect of feed (P = 0·30), but a significant main effect of time was observed (P < 0·001). (F + ALG, alginate-containing feed; F–ALG, alginate-free feed). GIP, glucose-dependent insulinotropic polypeptide; GLP-1, glucagon-like-peptide 1; PYY, peptide YY.

A significant feed-by-time interaction was seen (P = 0·002). On exploring simple effects, significantly lower levels were seen with F + ALG than with F-ALG at 100 min (P = 0·04), 120 min (P = 0·01), 140 min (P = 0·03), 160 min (P = 0·03) and 180 min (P = 0·03).

Plasma-active glucagon-like-peptide 1

Changes from baseline for plasma GLP-1 level are shown in Fig. 6(b). The values at baseline were similar (F + ALG = 3·4 ± 3·8 pg/ml and F-ALG = 3·8 ± 6·1 pg/ml) (P > 0·05)) and then increased once feeding commenced. Numerically, F + ALG showed a more blunted response appearing to return to baseline by 100 min, increase again and then return almost to baseline 3-h post-feeding. In contrast, numerically F-ALG showed a greater response and then oscillated at a higher level.

A significant feed-by-time interaction was seen (P = 0·02). On exploring simple effects, significantly lower levels were seen with F + ALG than with F-ALG at 60 min (P = 0·03), at 100 min (P = 0·001), at 120 min (P = 0·002) and at 180 min (P = 0·003).

Plasma peptide YY

Changes from baseline for plasma PYY levels are shown in Fig. 6(c). The values at baseline were similar (F + ALG = 74·4 ± 11·7 ml and F-ALG = 82·3 ± 7·7 ml; P = 0·52) briefly decreased once feeding commenced and then began to rise above baseline by 60 min. Numerically, F + ALG then returned to baseline by 120 min before demonstrating a blunted response compared with F-ALG which remained above baseline at 240 min.

No significant feed-by-time interaction was seen (P = 0·44); there was a significant main effect of feed (P = 0·004) with F-ALG being higher, and no main effect of time (P = 0·10).

Plasma ghrelin

Changes from baseline for plasma levels of ghrelin are shown in Fig. 6(d). The values at baseline were similar (F + ALG = 992·6 ± 354·0 pg/ml and F-ALG = 985·0 ± 222·8 pg/ml; P = 0·90). Once feeding commenced, numerically both levels decreased until 80 min with F + ALG and 100 min with F-ALG; with both the level returning to baseline by 240 min in both feeds.

There was a tendency for a significant feed-by-time interaction (P = 0·07), no significant main effect of feed (P = 0·3); there was a significant main effect of time (P < 0·001).

Appetitive VAS and pasta meal consumption

The time courses for appetitive VAS across the hour of feeding and 3-h postprandial are available in Supplementary Item 4. The difference in nAUC between F + ALG and F–ALG for ratings of hunger, satisfaction, fullness, desire to eat and prospective food consumption across the study were not significant (online Supplementary Item 5). Mean energy intake from the pasta meal, 3 h after 300 ml of enteral feed had been given was 7018·5 kJ ± 479·1 (F + ALG) and 8228·8 kJ ± 519·8 (F-ALG). The difference showed a tendency for a lower energy intake after F + ALG compared with F-ALG (P = 0·06).

Upper gastrointestinal symptom scores

The time courses for upper gastrointestinal symptom scores across the hour of feeding and 3-h postprandial are available in Supplementary Item 6. The differences in nAUC between F + ALG and F-ALG in reported upper gastrointestinal symptom scores from baseline to the end of the 3-h post-feeding period were not statistically significant (online Supplementary Item 7). Similarly, no statistically significant difference was seen between the two feeds when these symptoms were assessed on the day of intervention at bedtime (online Supplementary Item 8).

Discussion

The purpose of this study was to investigate in healthy participants whether acute exposure to an NGTF that forms an intragastric gel results in different gastrointestinal responses compared with a non-gelling feed. Using MRI, we demonstrated with the alginate-containing feed an intragastric appearance consistent with gelling, which previously has been shown only in animal studies(Reference Inoue, Kawashima and Hamada32) or in human studies following oral consumption(Reference Marciani, Gowland and Spiller53Reference Marciani, Lopez-Sanchez and Pettersson55). Whilst necessarily cautious in our interpretation of the visual appearance of the MRI images of the stomach contents as ‘consistent’ with gelling (given that the stomach contents were not observed directly) previous in vitro work (Supplementary Item 9) in which we simulated the acidic gastric environment, supports our conclusions. We noted differences in GCV and SBWC response between the two feeds.

GCV reduced more rapidly after F + ALG and individual GCV responses appeared less varied. The gut peptides GLP-1, GIP and PYY, which slow gastric emptying(Reference Camilleri56), increased as expected on initiation of feeding. Peripherally, GLP-1 is secreted from the intestinal L-cells following sensing of glucose and fat in the small bowel, although gastric distension also activates GLP-1-containing neurones in the nucleus of the solitary tract(Reference Camilleri56,Reference Janssen, Vanden Berghe and Verschueren57) . Initial gastric emptying occurs more rapidly (a shorter lag time) with liquids, compared with solids, of equivalent energy and macronutrient content(Reference Horowitz, Edelbroek and Wishart14,Reference Marciani, Gowland and Spiller53) and is slowed marginally by greater viscosity(Reference Marciani, Gowland and Spiller53,Reference Hoad, Rayment and Spiller54) . A nutrient poor liquid with low viscosity would be expected to leave the stomach more rapidly than the more viscous and nutrient-dense comparator feed, or a more viscous and nutrient-dense gel component. The halo of intragastric freely mobile liquid around the gel may have contributed to the more rapid reduction in GCV if of low viscosity and nutrient-poor, potentially due to selective nutrient retention by the gel, or if the gel resisted mixing with the less nutritive gastric secretions. The blunted gut peptide response would be consistent with a lower nutritive value liquid and would further perpetuate the more rapid reduction in GCV. Others have shown ‘sieving’ with a mixed consistency meal, resulting in rapid gastric emptying of a nutrient-poor liquid, compared with a soup with the solid and liquid components combined(Reference Marciani, Hall and Pritchard13). The contrast in texture, due to our study design, was less marked than previous studies, but some sieving may have occurred between the gel and liquid. The more rapid reduction in GCV, hence faster reduction in gastric distension, may contribute to a reduced risk of oesophageal reflux(Reference Holloway, Hongo and Berger24).

The similar levels of circulating glucose and serum insulin with the two feeds, in contrast to the blunted incretins GIP and GLP-1 with F + ALG, would refute a marked difference in the rate of delivery of at least glucose, to the small intestine. Similarly, no difference was seen in blood glucose profile when an alginate-containing drink was consumed orally(Reference Marciani, Lopez-Sanchez and Pettersson55). Furthermore, in our study, a similar SMA blood flux was seen with the two feeds, suggesting comparable stimulation with respect to glucose, at least(Reference Totman, Marciani and Foley42).

Alternatively, alginate reaching the small intestine may mask nutrient sensing if the gelling fibres interact with the intestinal mucus layer(Reference Mackie, Macierzanka and Aarak58) but appear not to mask the nutrients (e.g. glucose), with respect to stimulating SMA blood flux(Reference Totman, Marciani and Foley42) or prevent absorption. An in vitro ‘model gut’ might be used to establish whether there is selective retention of nutrients within the alginate gel(Reference Brodkorb, Egger and Alminger59).

We believe this study is the first to identify a difference in SBWC with an alginate-containing NGTF compared with a non-gelling feed. The initial reduction, below baseline with both feeds, in SBWC was comparable to other studies, including a comparison of bolus and continuous tube feeding(Reference Khalaf, Hoad and Menys49,Reference Chowdhury, Murray and Hoad60) and may reflect an anticipatory increased absorption (despite bypassing the cephalic phase)(Reference O’Keefe, Lee and Anderson61); early nutrient delivery(Reference Khalaf, Hoad and Menys49) which would be consistent with the numerical increase in SMA blood flux(Reference Totman, Marciani and Foley42); and early gastroileal reflex activation promoting distal ileal emptying into the ascending colon(Reference Khalaf, Hoad and Menys49).

The subsequent progressive increase in SBWC, with both feeds, has been attributed to pancreato-biliary and enterocyte secretions in the ‘intestinal phase’ combined with greater movement of mobile water from the stomach(Reference Khalaf, Hoad and Menys49). The numerically greater rebound, above baseline, after 180 min, with F + ALG is exemplified by more ‘bright-white’ freely mobile water in the MRI images at 210 min. Gel dissolving in the higher pH of the small bowel may have released bound water, or the blunting of the postprandial secretion of PYY, following distal small bowel nutrient sensing(Reference Camilleri56), may have contributed to the difference with the alginate feed. PYY is a major pro-absorptive hormone(Reference Camilleri56,Reference Adrian, Ferri and Bacarese-Hamilton62,Reference Wapnir and Teichberg63) and influences SBWC by strongly inhibiting gastrointestinal motility, and pancreatic, gastric, and small bowel secretions(Reference Camilleri56). PYY also triggers the ‘ileal brake’; hence, it slows intestinal transit, increasing half-time available for water absorption within the small intestine(Reference Camilleri56,Reference Camilleri64) . The clinical impact of the small difference in SBWC between the two feeds (maximum difference approximately 60 ml at 210 min and 240 min) seen in our study might be explored by measuring colonic water using a validated MRI technique(Reference Pritchard, Marciani and Garsed65) whilst concurrently quantifying stool consistency in healthy and patient groups who were chronically administered a NGTF.

The relatively small volume of feed given may have reduced the effect on appetite in contrast to other studies(Reference Hoad, Rayment and Spiller54) where addition of alginate increased satiation, although the oral route had been used(Reference Hoad, Rayment and Spiller54). Absence of a marked difference in energy intake from the pasta meal was not unexpected, given that ghrelin levels had returned to baseline with both feeds prior to consumption of the pasta.

Compliance with the upper gastrointestinal symptom scores recording and completion of the fecal charts, and fecal sample collection was high and gave no evidence of changed or abnormal bowel habits or symptoms with either feed. This may reflect the young, healthy nature of the participants and the small amount of feed provided.

The feeds had comparable energy, macronutrients, osmolarity and fibre content. The different fibre sources, however, may have confounded our interpretation of the results. The Scientific Advisory Committee on Nutrition (SACN, 2015) defines dietary fibre as including all carbohydrates that are neither digested nor absorbed in the small intestine and which have a degree of polymerisation of three or more monomeric units, plus lignin(66). Different dietary fibres, however, exhibit diverse chemical and physical properties(66,Reference Williams, Grant and Gidley67) , including the production of SCFA on fermentation in the colon, and may impact gastric emptying, SBWC, glycaemic and appetitive responses(Reference Mizuno, Bamba and Abe33,Reference Gunn, Abbas and Harris68Reference Meng, Matthan and Ausman71) . The acute nature of our study (over 4 h) and the single exposure to each feed (hence precluding microbial changes seen with prebiotics which stabilise over 6 weeks(Reference Williams, Grant and Gidley67)) were intended to limit the impact of any differences in fermentation and SCFA production, particularly in the earlier stages of the study, between the two feeds. Moreover, in our study, the SBWC profile for the inulin containing comparator feed was similar to that seen in the fibre-free arm of a previous study(Reference Chowdhury, Murray and Hoad60), although the return to baseline 240 min was less marked. A sufficiently stable feed that was identical, apart from the absence of alginate, was not available to us, due to production challenges but would benefit future studies.

We acknowledge that GCV is a proxy for gastric emptying, as it includes gastric secretions and rate of delivery of feed into the stomach (the latter identical in the two feeds in this study by design) as well as passage of gastric contents out of the stomach. Differences in gastric secretions are thought to be unlikely between the two feeds as the energy and macronutrient content were the same and delivery volume is considered to be more important than content with respect to gastric responses(Reference Janssen, Vanden Berghe and Verschueren57). Calculation of gastric emptying rate and time to 50 % of emptying were not considered valid, because the feed was delivered over a 60-min period rather than as a discrete bolus.

Difficulties with cannulation resulted in a smaller sample than intended for the blood-based measurements. This may have resulted in an increased risk of type 2 errors. In future studies, more participants should be recruited in anticipation of this issue.

Conclusions

In this study using MRI, we have demonstrated that a NGTF containing alginate results in an intragastric appearance consistent with the development of a gel surrounded by a halo of freely mobile water. Differences in gastrointestinal response, including SBWC and GCV, were demonstrated between this feed and a non-gelling feed. The stability, however, of these differences over a longer feeding period and their clinical relevance are not fully understood. Future studies are required over a longer time, and in clinical populations using a gelling, alginate-containing feed and a matched alginate-free feed.

Acknowledgements

The authors would like to thank Sara Brown (David Greenfield Human Physiology Unit, University of Nottingham) and Lesley Martin (Sir Peter Mansfield Imaging Centre, University of Nottingham) for their support in setting up the screening and study visits. The authors are grateful to Andrew Cooper, Jan Alappadan Paul, Mehri Kaviani and Chris Bradley (Sir Peter Mansfield Imaging Centre, University of Nottingham) for the operation of the MRI scanner. The authors would like to thank Dr Elizabeth Simpson (School of Life Sciences, University of Nottingham) for sharing her experience of using the foot hotbox in the MRI. The authors would like to express their gratitude to the participants who contributed to the study.

This work was supported by KANEKA CORPORATION, Japan, financially and by support in kind by providing free of charge the two NGTF. M. Y. and H. I., who are employees of KANEKA CORPORATION, contributed to the study design, interpretation of the findings and preparation of the manuscript. M. Y. and H. I. also contributed the pre-work, demonstrated in Supplementary Item 9, establishing the in vitro gelling properties of different feeds under acidic conditions, to enable appropriate feed selection.

A. I. A. was supported by a PhD scholarship received from Tertiary Education Trust Fund (TETFUND) Nigeria through Gombe State University, Gombe, Nigeria (AIA).

H. I. and M. Y. are KANEKA CORPORATION Employees. IM was Professor of Metabolic Physiology at the University of Nottingham when this project was planned and when the research commenced. From August 2020 to 2022, he was Scientific Director of the Nestle Institute of Health Sciences and an employee of Société des Produits Nestlé SA, Switzerland, but had no direct involvement with the Clinical Nutrition aspects of Nestle.

The study research question was established by G. P. A., M. C., H. I., I. A. M., L. M., M. A. T and M. Y.; the study was designed by A. I. A., M. C., S. M. C., C. L. H., I. A. M., L. M., A. N, M. A. T.; and with M. Y. and I. H. who also shared pre-work establishing the gelling properties of different commercial feeds; the study was undertaken by A. I. A., S. M. C., L. M., A. N. and M. A. T.; data analysis was undertaken by A. I. A., S. M. C., C. L. H., M. H. A., L. M. and M. A. T.; findings were interpreted by A. I. A., G. P. A., M. C., SC, H. I., I. A. M., L. M., M. A. T. and M. Y.; the first draft was prepared by A. I. A., A. N., S. M. C. and M. A. T.; all authors contributed to critical revision of the manuscript for important intellectual content and approved the final version.

A. I. A., G. P. A., M. H. A., S. M. C., C. L. H., A. N.: None.

Supplementary material

For supplementary material/s referred to in this article, please visit https://doi.org/10.1017/S0007114523000302

References

BAPEN (2012) Nutrition Screening Survey in the UK and Republic of Ireland in 2011. Worcs: British Association for Parenteral and Enteral Nutrition.Google Scholar
Whelan, K, Judd, PA & Taylor, MA (2003) Defining and reporting diarrhoea during enteral tube feeding: do health professionals agree? J Hum Nutr Diet 16, 2126.CrossRefGoogle ScholarPubMed
Adam, S & Batson, S (1997) A study of problems associated with the delivery of enteral feed in critically ill patients in five ICUs in the UK. Intens Care Med 23, 261266.CrossRefGoogle ScholarPubMed
Eisenberg, P (2002) An overview of diarrhea in the patient receiving enteral nutrition. Gastroenterol Nurs 25, 95104.CrossRefGoogle ScholarPubMed
Bowling, TE (2010) Diarrhoea in the enterally fed patient. Frontline Gastroenterol 1, 140143.CrossRefGoogle ScholarPubMed
Blumenstein, I, Shastri, YM & Stein, J (2014) Gastroenteric tube feeding: techniques, problems and solutions. World J Gastroenterol 20, 85058524.CrossRefGoogle ScholarPubMed
Cara, KC, Beauchesne, AR, Wallace, TC, et al. (2021) Safety of using enteral nutrition formulations containing dietary fiber in hospitalized critical care patients: a systematic review and meta-analysis. J Parenteral Enteral Nutr 45, 882906.CrossRefGoogle ScholarPubMed
Tatsumi, H (2019) Enteral tolerance in critically ill patients. J Intens Care 7, 3040.CrossRefGoogle ScholarPubMed
Wilson, M (2008) Diarrhoea and its possible impact on skin health. Nurs Times 104, 4952.Google ScholarPubMed
Hodgkinson, B, Evans, D & Wood, J (2003) Maintaining oral hydration in older adults: a systematic review. Int J Nurs Pract 9, S19S28.CrossRefGoogle ScholarPubMed
Studer, P, Räber, G, Ott, D, et al. (2016) Risk factors for fatal outcome in surgical patients with postoperative aspiration pneumonia. Int J Surg 27, 2125.CrossRefGoogle ScholarPubMed
Achour, L, Méance, S & Briend, A (2001) Comparison of gastric emptying of a solid and a liquid nutritional rehabilitation food. Eur J Clin Nutr 55, 769772.CrossRefGoogle Scholar
Marciani, L, Hall, N, Pritchard, SE, et al. (2012) Preventing gastric sieving by blending a solid/water meal enhances satiation in healthy humans. J Nutr 142, 12531258.CrossRefGoogle ScholarPubMed
Horowitz, M, Edelbroek, M, Wishart, J, et al. (1993) Relationship between oral glucose tolerance and gastric emptying in normal healthy subjects. Clin Exp Diabetes Metab 36, 857862.Google ScholarPubMed
Bowling, TE (1995) The Sir David Cuthbertson Medal Lecture. Enteral-feeding-related diarrhoea: proposed causes and possible solutions. Proc Nutr Soc 54, 579590.CrossRefGoogle Scholar
Reis, AMD, Fruchtenicht, AV, Loss, SH, et al. (2018) Use of dietary fibers in enteral nutrition of critically ill patients: a systematic review. Rev Bras Ter Intensiva 30, 358365.CrossRefGoogle ScholarPubMed
Marciani, L, Cox, EF, Hoad, CL, et al. (2010) Postprandial changes in small bowel water content in healthy subjects and patients with irritable bowel syndrome. Gastroenterology 138, 469477.CrossRefGoogle ScholarPubMed
Undseth, R, Berstad, A, Kløw, NE, et al. (2014) Abnormal accumulation of intestinal fluid following ingestion of an unabsorbable carbohydrate in patients with irritable bowel syndrome: an MRI study. Neurogastroenterol Motil 26, 16861693.CrossRefGoogle ScholarPubMed
Lam, C, Sanders, DS, Lanyon, P, et al. (2019) Increased fasting small-bowel water content in untreated coeliac disease and scleroderma as assessed by magnetic resonance imaging. United Eur Gastroenterology J 7, 13531360.CrossRefGoogle ScholarPubMed
Debongnie, JC & Phillips, SF (1978) Capacity of the human colon to absorb fluid. Gastroenterology 74, 698703.CrossRefGoogle ScholarPubMed
Hammer, J & Phillips, SF (1993) Fluid loading of the human colon: effects on segmental transit and stool composition. Gastroenterology 105, 988998.CrossRefGoogle ScholarPubMed
Wu, K-L, Rayner, CK, Chuah, S-K, et al. (2014) Effect of liquid meals with different volumes on gastroesophageal reflux disease. J Gastroenterology Hepatol 29, 469473.CrossRefGoogle ScholarPubMed
Ukleja, A (2010) Altered GI motility in critically Ill patients: current understanding of pathophysiology, clinical impact, and diagnostic approach. Nutr Clin Pract 25, 1625.CrossRefGoogle ScholarPubMed
Holloway, RH, Hongo, M, Berger, K, et al. (1985) Gastric distention: a mechanism for postprandial gastroesophageal reflux. Gastroenterology 89, 779784.CrossRefGoogle ScholarPubMed
Fisher, RS, Malmud, LS, Roberts, GS, et al. (1977) The lower esophageal sphincter as a barrier to gastroesophageal reflux. Gastroenterology 72, 1922.CrossRefGoogle ScholarPubMed
Atkinson, M, Edwards, DA, Honour, AJ, et al. (1957) The esophogogastric sphincter in hiatus hernia. Lancet 273, 11381142.CrossRefGoogle Scholar
Heyland, DK, Drover, JW, Dhaliwal, R, et al. (2002) Optimizing the benefits and minimizing the risks of enteral nutrition in the critically ill: role of small bowel feeding. J Parenter Enteral Nutr 26, S51S55; discussion S6–S7.CrossRefGoogle ScholarPubMed
Marik, PE & Zaloga, GP (2003) Gastric v. post-pyloric feeding: a systematic review. Crit Care 7, R46R51.CrossRefGoogle Scholar
Stokke, BT, Draget, KI, Smidsrød, O, et al. (2000) Small-angle x-ray scattering and rheological characterization of alginate gels. 1. Ca−alginate gels. Macromolecule 33, 18531863.CrossRefGoogle Scholar
Funami, T, Fang, Y, Noda, S, et al. (2009) Rheological properties of sodium alginate in an aqueous system during gelation in relation to supermolecular structures and Ca2+ binding. Food Hydrocolloids 23, 746755.CrossRefGoogle Scholar
Nishitani, H, Sato, H, Fukuyama, D, et al. (2018 ) Fundamental physiochemical properties of dietary fibers used in enteral nutrition formula. Jpn J Food Chem Safety 25, 7075.Google Scholar
Inoue, H, Kawashima, Y, Hamada, K, et al. (2014) Functional evaluations of a new type formula that features a state change from liquid to semi-solidified state depending upon pH. e-SPEN J 9, e185e191.CrossRefGoogle Scholar
Mizuno, H, Bamba, S, Abe, N, et al. (2020) Effects of an alginate-containing variable-viscosity enteral nutrition formula on defecation, intestinal microbiota, and short-chain fatty acid production. J Funct Foods 67, 103852.CrossRefGoogle Scholar
Ishikawa, S, Matsumura, H, Tomitsuka, S, et al. (2019) Comparison of complications with semisolid versus liquid diet via nasogastric feeding tube after orthognathic surgery. J Oral Maxillofac Surg (Epublication ahead of print version 25 October 2018).CrossRefGoogle ScholarPubMed
Metcalfe, M & Goldman, E (1965) Validation of an inventory for measuring depression. Br J of Psychiatr 111, 240242.CrossRefGoogle ScholarPubMed
Garner, DM, Olmsted, MP, Bohr, Y, et al. (1982) The eating attitudes test: psychometric features and clinical correlates. Psychol Med 12, 871878.CrossRefGoogle ScholarPubMed
do Carmo, MM, Walker, JC, Novello, D, et al. (2016) Polydextrose: physiological Function, and Effects on Health. Nutrients 8, 553.CrossRefGoogle ScholarPubMed
Whelan, K, Judd, PA & Taylor, MA (2004) Assessment of fecal output in patients receiving enteral tube feeding: validation of a novel chart. Eur J Clin Nutr 58, 10301037.CrossRefGoogle ScholarPubMed
Bowling, TE, Cliff, B, Wright, JW, et al. (2008) The effects of bolus and continuous nasogastric feeding on gastro-oesophageal reflux and gastric emptying in healthy volunteers: a randomised three-way crossover pilot study. Clin Nutr 27, 608613.CrossRefGoogle ScholarPubMed
Liu, D, Moberg, E, Kollind, M, et al. (1992) Arterial, arterialized venous, venous and capillary blood glucose measurements in normal man during hyperinsulinaemic euglycaemia and hypoglycaemia. Diabetologia 35, 287290.CrossRefGoogle ScholarPubMed
Seaquist, ER (1997) Comparison of arterialized venous sampling from the hand and foot in the assessment of in vivo glucose metabolism. Metabolism 46, 13641366.CrossRefGoogle ScholarPubMed
Totman, JJ, Marciani, L, Foley, S, et al. (2009) Characterization of the time course of the superior mesenteric, abdominal aorta, internal carotid and vertebral arteries blood flow response to the oral glucose challenge test using magnetic resonance imaging. Physiol Meas 30, 11171136.CrossRefGoogle Scholar
Alhussain, MH, Macdonald, IA & Taylor, MA (2016) Irregular meal-pattern effects on energy expenditure, metabolism, and appetite regulation: a randomized controlled trial in healthy normal-weight women. Am J Clin Nutr 104, 2132.CrossRefGoogle ScholarPubMed
Wansink, B, Painter, JE & North, J (2005) Bottomless bowls: why visual cues of portion size may influence intake. Obes Res 13, 93100.CrossRefGoogle ScholarPubMed
McAuliffe, MJ, Lalonde, F, McGarry, DP, et al. (2001) Medical Image Processing, Analysis and Visualization in Clinical Research. Proceedings 14th IEEE Symposium on Computer-Based Medical Systems CBMS. pp. 381386.CrossRefGoogle Scholar
Hoad, CL, Marciani, L, Foley, S, et al. (2007) Non-invasive quantification of small bowel water content by mri: a validation study. Phys Med Biol 52, 69096922.CrossRefGoogle ScholarPubMed
Burkart, DJ, Felmlee, JP, Johnson, CD, et al. (1994) Cine phase-contrast MR flowmeasurements: improved precision using an automated method of vessel detection. J Assist Tomogr 18, 469475.CrossRefGoogle Scholar
Kozerke, S, Botnar, R, Our, S, et al. (1999) Automatic vessel segmentation using active contours in cine phase contrast flow measurementsJ. Magn Reson Imaging 10, 4151.3.0.CO;2-J>CrossRefGoogle Scholar
Khalaf, A, Hoad, CL, Menys, A, et al. (2018) MRI assessment of the postprandial gastrointestinal motility and peptide response in healthy humans. Neurogastroenterol Motil 30, e13182.CrossRefGoogle ScholarPubMed
Moran, GW, Leslie, FC & McLaughlin, JT (2013) Crohn’s disease affecting the small bowel is associated with reduced appetite and elevated levels of circulating gut peptides. Clin Nutr 32, 404411.CrossRefGoogle ScholarPubMed
Alyami, J, Whitehouse, E, Yakubov, GE, et al. (2019) Glycaemic, gastrointestinal, hormonal and appetitive responses to pearl millet or oats porridge breakfasts: a randomised, crossover trial in healthy humans. Br J Nutr 122, 11421154.CrossRefGoogle ScholarPubMed
Tack, J, Carbone, F, Holvoet, L, et al. (2014) The use of pictograms improves symptom evaluation by patients with functional dyspepsia. Aliment Pharmacol Ther 40, 523530.CrossRefGoogle ScholarPubMed
Marciani, L, Gowland, PA, Spiller, RC, et al. (2001) Effect of meal viscosity and nutrients on satiety, intragastric dilution, and emptying assessed by MRI. Am J Physiol Gastrointest Liver Physiol 280, G1227G1233.CrossRefGoogle ScholarPubMed
Hoad, CL, Rayment, P, Spiller, RC, et al. (2004) In vivo imaging of intragastric gelation and its effect on satiety in humans. J Nutr 134, 22932300.CrossRefGoogle ScholarPubMed
Marciani, L, Lopez-Sanchez, P, Pettersson, S, et al. (2019) Alginate and HM-pectin in sports-drink give rise to intra-gastric gelation in vivo. Food Funct 10, 78927899.CrossRefGoogle ScholarPubMed
Camilleri, M (2019) Gastrointestinal hormones and regulation of gastric emptying. Curr Opin Endocrinol Diabetes Obes 26, 310.CrossRefGoogle ScholarPubMed
Janssen, P, Vanden Berghe, P, Verschueren, S, et al. (2011) Review article: the role of gastric motility in the control of food intake. Aliment Pharmacol Ther 33, 880894.CrossRefGoogle ScholarPubMed
Mackie, AR, Macierzanka, A, Aarak, K, et al. (2016) Sodium alginate decreases the permeability of intestinal mucus. Food Hydrocoll 52, 749755.CrossRefGoogle ScholarPubMed
Brodkorb, A, Egger, L, Alminger, M, et al. (2019) INFOGEST static in vitro simulation of gastrointestinal food digestion. Nat Protoc 144, 9911014.CrossRefGoogle Scholar
Chowdhury, AH, Murray, K, Hoad, CL, et al. (2016) Effects of bolus and continuous nasogastric feeding on gastric emptying, small bowel water content, superior mesenteric artery blood flow, and plasma hormone concentrations in healthy adults: a randomized crossover study. Ann Surg 263, 450457.CrossRefGoogle ScholarPubMed
O’Keefe, SJD, Lee, RB, Anderson, FP, et al. (2003) Physiological effects of enteral and parenteral feeding on pancreaticobiliary secretion in humans. Am J Physiol-Gastrointest Liver Physiol 284, G27G36.CrossRefGoogle ScholarPubMed
Adrian, TE, Ferri, GL, Bacarese-Hamilton, AJ, et al. (1985) Human distribution and release of a putative new gut hormone, peptide YY. Gastroenterology 89, 10701077.CrossRefGoogle ScholarPubMed
Wapnir, RA & Teichberg, S (2002) Regulation mechanisms of intestinal secretion: implications in nutrient absorption. J Nutr Biochem 13, 190199.CrossRefGoogle ScholarPubMed
Camilleri, M (2004) Chronic diarrhea: a review on pathophysiology and management for the clinical gastroenterologist. Clin Gastroenterology Hepatol 2, 198206.CrossRefGoogle ScholarPubMed
Pritchard, SE, Marciani, L, Garsed, KC, et al. (2014) Fasting and postprandial volumes of the undisturbed colon: normal values and changes in diarrhea-predominant irritable bowel syndrome measured using serial MRI. Neurogastroenterol Motil 26, 124130.CrossRefGoogle ScholarPubMed
SACN (2015) Carbohydrates and Health. London: Scientific Advisory Committee on Nutrition.Google Scholar
Williams, BA, Grant, LJ, Gidley, MJ, et al. (2017) Gut fermentation of dietary fibres: physico-chemistry of plant cell walls and implications for health. Int J Mol Sci 18, 2203.CrossRefGoogle ScholarPubMed
Gunn, D, Abbas, Z, Harris, HC, et al. (2022) Psyllium reduces inulin-induced colonic gas production in IBS: MRI and in vitro fermentation studies. Gut 71, 919927.CrossRefGoogle ScholarPubMed
Berthold, HK, Unverdorben, S, Degenhardt, R, et al. (2008) Effect of a cellulose-containing weight-loss supplement on gastric emptying and sensory functions. Obesity 16, 22722280.CrossRefGoogle ScholarPubMed
Slavin, JL, Savarino, V, Paredes-Diaz, A, et al. (2009) A review of the role of soluble fiber in health with specific reference to wheat dextrin. J Int Med Res 37, 117.CrossRefGoogle ScholarPubMed
Meng, H, Matthan, NR, Ausman, LM, et al. (2017) Effect of macronutrients and fiber on postprandial glycemic responses and meal glycemic index and glycemic load value determinations. Am J Clin Nutr 105, 842853.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Composition of the two feeds per 300 ml

Figure 1

Fig. 1. The flow of the participants from screening to final data analysis. All blood samples analysed were for seven participants except for GLP-1 (n 6) where one participant was excluded from analysis due to abnormally low levels which were undetectable. GLP-1, glucagon-like-peptide 1.

Figure 2

Fig. 2. T2-weighted (TE = 300) axial images of the stomach showing characteristics of intragastric contents for the two feeds (F + ALG and F-ALG) 90 min after the commencement of feeding in one of the participants. The green arrows indicate the gastric contents. The freely mobile water appears as a bright white halo around a darker intragastric feed region which has a gel-like appearance, with F + ALG (left-hand image). The greyer appearance of the homogenous feed can be seen with F-ALG with no freely mobile water visualised as a bright white signal (right-hand image). F + ALG, alginate-containing feed; F–ALG, alginate-free feed; TE, echo time.

Figure 3

Table 2. Baseline characteristics of participants whose data were analysed (n 10)

Figure 4

Fig. 3. Change from baseline for small bowel water contents volume (SBWC) (a), gastric contents volume (GCV) (b) and superior mesenteric artery (SMA) blood flux (c) through 1 h of feeding and 3-h post-feeding (mean ± sem) in F + ALG and F-ALG (n 10). (a): For SBWC volume, no significant feed-by-time interaction was seen (P = 0·120). There was a statistically significant main effect for feed (P = 0·03) with the SBWC volume being greater for F + ALG compared with F-ALG and a significant main effect for time (P < 0·001). (b) For GCV, there was a statistically significant feed-by-time interaction (P = 0·04). Pairwise comparison between feeds revealed no significant difference in GCV for each of the time points (P > 0·05). (c): For SMA blood flux, there was no significant feed-by-time interaction (P = 0·22) or main effect of feed (P = 0·34), although there was a main effect of time (P < 0·001). F + ALG, alginate-containing feed; F–ALG, alginate-free feed.

Figure 5

Fig. 4. Coronal images of the abdomen in a single representative participant with the freely mobile water in the small bowel showing as bright white areas for F + ALG (a) and F-ALG (b), taken at 210 min after the commencement of feeding. More freely mobile water is evident with more bright white areas in A with F + ALG. (F + ALG, alginate-containing feed; F–ALG, alginate-free feed).

Figure 6

Fig. 5. Change from baseline for serum insulin through 1 h of feeding and 3-h post-feeding (mean ± sem) in F + ALG and F-ALG feeds (n 7). No significant feed-by-time interaction (P = 0·69) was seen, but there was a significant main effect of feed (P = 0·01) and time (P < 0·001). (F + ALG, alginate-containing feed; F–ALG, alginate-free feed).

Figure 7

Fig. 6. Change from baseline for (a) serum total GIP (n 7), (b) plasma-active GLP-1 (n 6), (c) plasma PYY (n 7) and (d) plasma ghrelin (n 7), through 1 h of feeding and 3-h post-feeding (mean ± sem) for F + ALG and F-ALG. (a) (serum total GIP): There was a significant feed-by-time interaction (P = 0·002). Pairwise comparison showed significantly lower levels with F + ALG than with F-ALG at 100 min (P = 0·04), 120 min (P = 0·01), 140 min (P = 0·03), 160 min (P = 0·03) and 180 min (P = 0·03). (b) (plasma-active GLP-1): There was a significant feed-by-time interaction (P = 0·02). Pairwise comparison showed significantly lower levels with F + ALG than with F-ALG at 60 min (P = 0·03), 100 min (P = 0·001), 120 min (P = 0·002) and 180 min (P = 0·003). (c) (plasma PYY): No feed-by-time interaction (P = 0·44) was seen, but a main effect of feed (P = 0·004) was observed with no significant main effect of time (P = 0·10). (d) (plasma ghrelin): There was a tendency for a feed-by-time interaction observed (P = 0·07), no significant effect of feed (P = 0·30), but a significant main effect of time was observed (P < 0·001). (F + ALG, alginate-containing feed; F–ALG, alginate-free feed). GIP, glucose-dependent insulinotropic polypeptide; GLP-1, glucagon-like-peptide 1; PYY, peptide YY.

Supplementary material: File

Aliyu et al. supplementary material

Aliyu et al. supplementary material

Download Aliyu et al. supplementary material(File)
File 1.1 MB