The water load test: observations from healthy controls and patients with functional dyspepsia

Michael P. Jones, Seth Hoffman, Dhiren Shah, Ketan Patel, and Christine C. Ebert

Division of Gastroenterology and Hepatology, Northwestern University Medical School, Chicago, Illinois 60611-2908


    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Gastric sensation and accommodation are studied by barostat, but this is invasive. The drink test is noninvasive and may provide similar information. We evaluated relationships between drink test, gastric function, symptoms, and psychiatric distress. Controls (73) and functional dyspeptics (FD) (92) were studied using a 5-min water load test (WL5), gastric emptying, and electrogastrography (EGG). Symptoms, quality of life, and psychiatric distress were measured using standardized measures. Controls underwent test-retest of WL5 and comparison of WL5 with 100 ml/min water-based drink test (WL100) or nutrient drink. Controls, FD, and gastroparetics estimated drinking capacity before WL5 using a visual analog scale. WL5 correlated with WL100 (r = 0.7929) but not nutrient drink test (r = 0.1995). WL5 was significantly less in FD than controls, and abnormal WL5 was seen in 46%. In FD, volume to fullness inversely correlated with symptom severity (r =-0.29; P = 0.0154) and WL5 produced more symptoms, particularly nausea. Gastric function was not different between FD with normal or abnormal WL5. Symptoms and psychiatric distress were similar between normal and abnormal WL5 groups, but the abnormal group had significantly poorer quality of life. Controls and gastroparetics had good correlation of estimated and ingested volumes, but FD did not. Versus FD with normal WL5 capacity, FD with impaired drinking capacity have normal gastric function and similar symptoms but poorer quality of life. FD are less able to predict drinking capacity. These data suggest that WL5 identifies FD with intact gastric function but abnormal visceral perception.

satiety; dyspepsia; gastric function; visceral perception


    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

FUNCTIONAL DYSPEPSIA (FD) is a common, often difficult problem in clinical practice. The pathophysiology of the disorder is likely heterogeneous with a number of mechanisms proposed. These include gastric and small intestinal motor abnormalities, visceral hypersensitivity, and psychological factors. Recent investigations have focused on impaired meal-induced fundic relaxation as well as visceral hypersensitivity (14, 21, 25, 29, 33, 35). These studies have generally been performed using a barostat with an intragastric balloon. Although the utility of the barostat to study mechanical properties of the proximal stomach is well established, its utility as an investigational or clinically applicable device in the investigation of FD is questionable. The technique is cumbersome, not widely available, and unpleasant.

The investigation of patients with functional or neuromuscular digestive disorders, whether from a clinical or research point of view, will benefit from minimally invasive, patient-friendly techniques that are sensitive, reproducible, and can be applied across large study populations. The water load or drink test is such a tool that was developed as a noninvasive method to assess gastric sensation. The test is easily performed and well tolerated, and preliminary studies have demonstrated reproducibility in healthy adults (11, 15, 34). FD patients have been shown to have impaired drinking capacity, although there is substantial overlap with normal subjects (13, 15, 34).

Initial studies of the drink test suggested that it correlated well with barostat studies (1). Boeckxstaens et al. (3), however, recently showed that a drink test using either water or a caloric drink was a less sensitive predictor of impaired accommodation or visceral hypersensitivity than the barostat. It thus appears that, although the results of drink tests are due at least in part to gastric sensation and motor function, the test may also be influenced by sensory and psychological factors. The present study was undertaken to further evaluate the performance characteristics of the drink test in both healthy controls and patients with FD.

The primary aim of this study was to determine the utility and clinical correlates of the water load test in FD. To achieve this, we first established normal values and test characteristics for the 5-min water load test (WL5) and compared it with other methods of "stomach loading." We also administered WL5 to patients with FD and correlated the volume required to produce fullness with gastric emptying, electrogastrography (EGG), symptom severity, quality of life, and psychopathological variables.


    METHODS
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Subjects. Healthy volunteers were recruited by advertisement. Exclusion criteria included prior gastrointestinal surgery (except appendectomy), presence of any digestive complaints, or the use of any medications to treat digestive disorders or medications that might alter digestive motility.

Patients with FD were consecutively enrolled from the Gastrointestinal Physiology Laboratory after being referred from the outpatient gastroenterology clinic at Northwestern University. Although enrollment from the Physiology Laboratory was consecutive, it was not possible to know the total pool of dyspeptics from which these subjects were selected. Patients were eligible if they met Rome II criteria for FD (31). Patients were excluded if they had dominant complaints of heartburn, prior digestive surgery other than cholecystectomy or appendectomy, or were taking medications known or suspected of altering digestive motility. All subjects were required to have a normal upper gastrointestinal endoscopy, with further evaluation performed as indicated by the evaluating gastroenterologist. Patients with FD were further categorized using Rome II guidelines as ulcer-like dyspepsia or dysmotility-like dyspepsia. Patients were considered to have ulcer-like dyspepsia if the predominant symptom was pain centered in the upper abdomen. Patients were considered to have dysmotility-like dyspepsia if their predominant symptom was a nonpainful sensation characterized or associated with upper abdominal fullness, early satiety, bloating, or nausea. Subjects were allowed to remain on acid suppressive therapy because proton pump inhibitors do not alter gastric emptying, EGG, or the volume of water required to produce satiety (12).

Subjects were also excluded if they were infected with Helicobacter pylori. H. pylori status was determined by either biopsy for histology or rapid urease testing, whole blood serology, or 13C-urea breath testing. For purposes of this study, patients were considered infected if any test for the presence of H. pylori was positive.

All dyspeptics were referred for and underwent EGG and the water load test and completed symptom and psychosocial questionnaires. A subset of these patients were either referred directly for gastric emptying using the 13C-urea breath test or agreed to also undergo this test.

For comparative purposes, patients with documented diabetic or idiopathic gastroparesis and gastroesophageal reflux disease (GERD) were also evaluated. Gastroparesis was defined as scintigraphic evidence of delayed gastric emptying along with documented gastric stasis as well as a dominant symptom of vomiting. GERD was defined as a dominant symptom of heartburn with endoscopy demonstrating hiatal hernia and/or esophagitis and a clinical response to acid suppressive therapy.

The protocol was approved by the Northwestern University Institutional Review Board.

Drink testing. All subjects were studied after an overnight fast. WL5 was performed by having subjects drink room-temperature tap water ad libitum over a 5-min period until reaching the point of fullness. Water was consumed from an unmarked flask that was taken from the subject and refilled after each drink. The volume required to refill the flask to the initial level was recorded, and the total volume consumed was calculated by summing these volumes. In this way, the flask was "bottomless" and the subject was blinded as to the actual volume of water consumed.

A group of healthy controls also underwent satiety testing by ingesting, on separate occasions, water at rate of 100 ml/min until full (WL100) or a liquid meal over 5 min until full (LM). The LM was administered using an identical method to WL5. WL100 has been reported by Boeckxstaens and colleagues in several studies on proximal gastric function (2, 3). LM is a method similar to that used by both Boeckxstaens et al. (2, 3) and Tack et al. (29) but did differ, however, in that we used Boost for the test meal (Mead Johnson Nutritionals, Evansville, IN). Boost contains 1.1 kcal/ml and is 70% carbohydrate, 15% fat, and 16% protein, compared with Nutridrink (N.V. Nutricia, Zoetermeer, Netherlands), which contains 1.5 kcal/ml and is 39% fat. Symptoms of nausea, fullness, and bloating were rated using a four-point Likert scale (none, mild, moderate, and severe). Symptoms were assessed at baseline and at 10, 20, and 30 min after completion of the drink test.

EGG. EGG was performed after a 12-h overnight fast using a Cycle3 EGG machine (3CPM, Crystal Bay, NV). After skin preparation, three standard Ag-AgCl electrodes (SensorMedics, Anaheim, CA) were positioned on the anterior abdominal surface. One electrode was positioned midway between the xiphoid and umbilicus. A second electrode was placed just below the costal margin in the left midclavicular line. A reference electrode was placed just below the costal margin in the right midclavicular line. Electrodes were connected to a BMA-931 Bioamplifier with frequency cutoffs set at 0.016 Hz and 0.25 Hz (0.95 and 15 cpm). Output from the bioamplifier was simultaneously sent to a strip chart recorder as well as being digitized at a sampling frequency of 4.267 Hz and stored in a PC for further analysis. A pneumobelt was placed around the patient's upper abdomen and connected to a pressure transducer to record respiratory rate. All recordings were performed in a quiet room with the subject instructed not to talk and to remain as still as possible during recording to minimize motion artifacts.

After signal stabilization, baseline tracing was performed for 15 min. This was followed by the drink test. After completion of the drink test, recording was continued for an additional 30 min.

The raw EGG tracing was inspected, and segments with artifact were excluded. The digitized signal was Fourier transformed, and a running spectral analysis (RSA) was generated using a 4-min epoch with 75% overlap as previously described by Koch et al. (16). EGGs were classified as normal, abnormal, or technically inadequate based on the raw signal, the RSA, and the percentage of EGG signal power in various bandwidths. An EGG was considered normal if there was a dominant frequency between 2.5 and 4 cpm for >70% of the study period. The study was considered abnormal if 2- to 4-cpm activity was seen for <70% of the time. Activity of 0.95-2.4 cpm was considered bradygastria, and activity of 4-15 cpm was considered tachygastria. Tracings were considered technically inadequate if there was excessive artifact, persistently low amplitude signal, or an RSA demonstrating numerous, chaotic peaks.

Gastric emptying. Determination of solid-phase gastric emptying was performed using the 13C-Spirulina platensis gastric emptying breath test (Meretek Diagnostics, Houston, TX). We employed a similar method to that reported by Lee et al. (19). The S. platenses used in this study was grown in a closed hydroponic chamber purged with pure 13CO2 and was uniformly labeled with 13C. As a result, the level of 13C is increased from normal background levels of ~1% to ~99%.

Gastric emptying was measured after an overnight fast. Subjects ingested a standard test meal that consisted of a 60-g rye roll (160 kcal), 30 g cream cheese (90 kcal), and 120 ml white grape juice (80 kcal). The rye roll contained 200 mg of 13C-S. platensis. Breath samples were collected at baseline and at 45, 90, 105, and 150 min after ingesting the test meal.

13C breath enrichment was determined using isotope ratio mass spectrometry performed using an automated breath 13C analyzer (PDZ Europa; Cheshire, UK). 13CO2 in a breath sample was calculated as the percentage of 13CO2 in total CO2 above background 13CO2 concentrations in nature. Results were expressed as both the percentage of 13CO2 recovery and the cumulative recovery over the study period. CO2 production was assumed to be 300 mmol/m2 body surface area as has been previously determined (8). Body surface area was calculated from existing height-weight nomograms.

Determination of the quantity of 13CO2 in breath per unit time was performed using delta over baseline (DOB): 13C (µM/min) = DOB × 0.0112372 × CO2 production. The constant in this equation is the isotopic abundance of Pee Dee Belemnite, which is a limestone standard. CO2 production was corrected for age and gender as determined by Schofield (26).

Calculation of half-time for solid emptying (T1/2) and the lag phase (Tlag) were made using the mathematical model derived by Lee et al. (19). T1/2 = 1/LP1/2, where LP1/2 = 0.0097 + 0.0021(13C105- 0.0012(13C150). Determination of Tlag was made using Tlag = 1/LPlag, where LPlag = 0.250 + 0.0063(13C90- 0.0032(13C150). LP1/2 and LPlag are the linear predictors, and 13C90, 13C105, and 13C150 are the excreted concentrations of 13C (µmol/min) at 90, 105, and 150 min after ingestion of the test meal.

Questionnaires. Subjects were asked to complete several self-report measures pertaining to symptomatology, quality of life, and psychopathologic traits. FD severity was evaluated using the Nepean Dyspepsia Index (NDI). This is a validated, disease-specific measure that evaluates symptoms related to FD over the 2-wk before administration (30, 32). Raw scores were converted into percentage scores for comparative purposes. Ability to predict the volume of water required to produce fullness was determined in a subset of subjects. Before the water load test, subjects estimated the volume they could ingest on a 100-mm visual analog scale with the endpoints "almost none" and "a very large amount."

Quality of life was assessed using two general measures, the SF-36 and the Psychological General Well Being Index (PGWB). The SF-36 is a widely used and well-studied measure that assesses symptom impact on eight subscales that are broadly grouped into mental and physical well being (7, 24, 36). Although a nonspecific measure, the SF-36 has been used in a variety of digestive disorders including FD (20). The PGWB is an index to measure a person's subjective well-being. The person self-reports on 22 items that are indicators of the affective states of anxiety, depressed mood, sense of positive well-being, self-control, general health, and vitality (6).

Psychiatric distress was measured using the SCL-90. The SCL-90 is a self-reporting, clinical symptom rating scale consisting of 90 questions. Responses indicate symptoms associated with nine psychiatric constructs. These constructs are somatization, obsessive-compulsive behavior, feelings of inadequacy or inferiority (interpersonal sensitivity), depression, anxiety, hostility, phobic anxiety, paranoid ideation, and psychoticism (5).

Study protocol. All studies were performed after a 12-h overnight fast. Informed consent was obtained before evaluation for all subjects. Healthy subjects and patients meeting Rome II criteria for FD completed the drink testing using WL5. A subset of healthy subjects underwent WL5 on a second occasion at least 2 wk after the initial testing session. A subset of these subjects also underwent WL5 on a third occasion at least 2 mo after the initial testing session. A second subset of controls underwent, in addition to WL5, WL100 and LM. Subjects also underwent gastric emptying and EGG and completed the NDI, SF-36, PGWB, and SCL-90.

Statistical analysis. Data were expressed as means ± SD. Normality of all data sets was determined using the Kolmogorov-Smirnov test. For normally distributed data, correlations were calculated using the Pearson method, and differences between groups were determined using paired or unpaired t-tests. In several of the symptom comparisons, all values in the control group were zero. In these instances, comparisons were made using a one-sample t-test for the FD group compared with a hypothetical mean of zero. Correlations between non-normally distributed data sets were determined using the Spearman method, whereas differences between median group scores were determined using the Mann-Whitney test. Statistical significance was set at P < 0.05. Statistical calculations were made using GraphPad Prism version 3.00 for Windows (GraphPad Software, San Diego, CA).


    RESULTS
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Normal values for WL5. Seventy-three healthy subjects were evaluated. This group included 29 males and 44 females with a mean age of 29 ± 5 yr. The mean volume required to produce fullness was 648 ± 204 ml. Males (703 ± 217 ml) drank more than females (611 ± 188 ml), but the difference did not reach statistical significance (t = 1.907; P = 0.0605). These data are shown in Fig. 1. No healthy subject consumed <300 ml of water.


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Fig. 1.   Water volumes required to produce satiety in healthy subjects. Whereas males generally consumed more water than females, the difference between the groups did not reach statistical significance. Horizontal bars represent group means.

Significant correlations also existed between the volume to produce fullness and age (r = 0.3536; P = 0.0070) and height (r = 0.2625; P = 0.0486) but not BMI (r = 0.1377; P = 0.3069). Gastric emptying studies were performed in 26 subjects, and EGG was performed in 41 subjects. There was no correlation between volume to fullness and Tlag (r = -0.1532; P = 0.4549) or T1/2 (r = -0.1489; P = 0.4679). Abnormal EGGs were seen in 4 of 41 healthy subjects, all of whom manifested bradygastria. No differences existed between subjects with normal or abnormal EGGs and the volume required to produce fullness (t = 0.004; P = 0.9965).

In healthy subjects, there was no significant correlation between volume to produce fullness and NDI (r = -0.3267; P = 0.1033), PGWB (r = 0.05717; P = 0.777), SF-36 mental composite (r = 0.1698; P = 0.3971), and physical composite scores (r = 0.06486; P = 0.7479) or SCL-90 (r = -0.1298; P = 0.5273) scores.

Reproducibility of WL5. Forty-three healthy subjects underwent WL5 on two occasions separated by at least 2 wk, and 20 of these subjects were studied on a third session at least 2 mo after the index drink test (Fig. 2). For the 20 subjects assessed on 3 occasions, volumes to fullness were slightly but not significantly lower at subsequent sessions (570 ± 199 vs. 540 ± 154 vs. 515 ± 146; P = 0.3684). Volume to fullness between the first and second session (WL51 and WL52) was highly correlated (r = 0.7729; P < 0.0001). The mean difference between WL51 and WL52 was 33 ± 170 ml. Correlation between WL51 and the third measurement (WL53) was poor (r = 0.3263; P = 0.1603). The mean difference between WL51 and WL53 was 55 ± 204 ml.


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Fig. 2.   Repeatability of the 5-min water load test (WL5). Forty-two healthy subjects were studied on two separate occasions at least 2 wk apart. Twenty of these subjects were also studied on a third occasion at least 2 mo after the initial test. WL51, first drink test; WL52, second drink test; WL53, third drink test. Dashed lines represent the 95% confidence intervals for the regression line.

Comparison of WL5, WL100, and LM. Eighteen healthy subjects (9 female/9 male) underwent both WL5 and WL100, and 15 of these subjects also underwent LM. Testing by each method was separated by at least 2 wk. Results are shown in Fig. 3. The two water-based methods were highly correlated (r = 0.7929; P < 0.0001), whereas the correlation between WL5 and LM was poor (r = 0.1995; P = 0.4760). The mean volume to fullness for WL100 was 1128 ± 355 ml compared with 889 ± 270 ml for WL5 (P = 0.0002). Mean volume for LM (688 ± 187 ml) was significantly lower than either WL100 (P = 0.0003) or WL5 (P = 0.0360).


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Fig. 3.   Comparison of satiety test methods. The two water-based methods are significantly correlated, whereas the caloric drink test is not. Volumes for all methods differ significantly. *P = 0.0002 for 100 ml/min water load test (WL100) vs. WL5; **P = 0.0003 for WL100 vs. liquid meal (LM); #P = 0.0360 for LM vs. WL5.

FD. Eighty-seven FD patients were evaluated. The FD population was slightly older than the control population (36 ± 14 vs. 29 ± 5 yr; t = 3.624; P = 0.004). The group contained 21 males and 66 females, which was a greater representation of females than the control group (76 vs. 60%; P = 0.0405). Sixty-nine of the FD subjects were considered motility-like with dominant symptoms of nausea, bloating, or early satiety. Eighteen subjects were considered ulcer-like because they had a dominant symptom of upper abdominal pain. FD subjects required significantly less water to produce fullness than did controls (333 ± 235 ml vs. 648 ± 204 ml; t = 8.953; P < 0.0001). No difference in volume to fullness was seen between ulcer-like dyspeptics (357 ± 231 ml) and dysmotility like dyspeptics (325 ± 237 ml; P = 0.6126). Males and females with FD required significantly less water to produce fullness than did healthy subjects of the same sex (Fig. 4).


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Fig. 4.   Volumes required to produce satiety in healthy subjects and patients with functional dyspepsia using WL5. Male and female dyspeptics ingested significantly less water than healthy subjects. #P < 0.0001 vs. controls; *P < 0.005 vs. controls of the same sex; **P = 0.0013 vs. functionally dyspeptic males.

FD subjects were more symptomatic during the study than were healthy subjects (Fig. 5). Symptoms at baseline and at all three postingestion periods were greater in the FD subjects than in controls (nausea, P < 0.0001; fullness, P < 0.0009; bloating, P < 0.006). For controls there was no correlation between ingested volume and symptoms of nausea, fullness, or bloating at any time point. For FD subjects, significant negative correlations existed between WL5 volume and baseline symptoms of nausea (rs = -0.3748; P = 0.0005) and fullness (rs = -0.2465; P = 0.0256) but not bloating. Post-WL5 symptoms of nausea demonstrated significant negative correlations at 10 (rs = -0.4272; P < 0.0001), 20 (rs = -0.3822; P = 0.0004), and 30 min (rs = -0.3834; P = 0.0007) after ingestion. Significant correlations were not seen for postprandial symptoms of fullness and bloating or for volume to fullness.


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Fig. 5.   Symptoms before and after WL5 in healthy controls and functional dyspeptics. Dyspeptics are significantly more symptomatic in terms of nausea (A), fullness (B), and bloating (C) both at baseline and after WL5. All time points were significantly different between the two groups. P1, 10 min after WL5; P2, 20 min after WL5; P3, 30 min after WL5. Data are means ± SD.

EGG was performed in 84 of 87 subjects and was abnormal in 36 of 84 (43%). The abnormalities seen consisted of bradygastria in 16, bradyarrhythmia in 12, and diffuse arrhythmia in 8. FD patients with an abnormal EGG reached fullness at significantly greater volumes than did patients with normal EGGs (416 ± 279 vs. 265 ± 171 ml; t = 3.056; P = 0.0030). Gastric emptying studies were performed in 42 subjects. Volume to fullness was not correlated with T1/2 (r = 0.2624; P = 0.0932) but was correlated with Tlag (r = 0.3336; P = 0.0330).

Compared with healthy subjects, FD subjects had significantly greater symptom severity as measured by NDI (t = 12.03; P < 0.0001). As shown in Fig. 6, there is also significantly reduced quality of life as measured by both PGWB and SF-36 (P < 0.0001 for both). These differences were seen for all subscale scores of the SF-36. FD subjects also displayed stronger responses to the psychological queries of the SCL-90. Again, the differences between the two groups were seen with all subscales of the SCL-90 but were most striking for the categories of somatization and depression.


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Fig. 6.   Comparison of symptom severity, quality of life, and psychometric assessment in healthy subjects and patients with functional dyspepsia. The SF-36 scales are as follows: PF, physical functioning; RP, role physical; BP, bodily pain; SF, social functioning; MH, mental health; RE, role emotional; VT, vitality; GH, general health. Tests included the Psychological General Well Being Index (PGWB) and the Nepean Dyspepsia Index (NDI).

Among the dyspeptics, there was a modest, negative correlation between volume to fullness and NDI score (r = -0.2906; P = 0.0154). WL5 was not correlated with total PGWB score or any subscale score other than general health (r = 0.3140; P = 0.0064). For SF-36, significant correlations existed on the physical functioning (r = 0.2394; P = 0.04) and social functioning (r = 0.2837; P = 0.0143) subscales. No correlation was seen with total SCL-90 score or any subscales other than interpersonal sensitivity (r = 0.2810; P = 0.0185) and paranoid ideation (r = 0.2936; P = 0.0136).

Because no healthy control consumed <300 ml of water, we compared functional dyspeptics with WL5 < 300 ml with WL5 >=  300 ml (Table 1). Forty-one functional dyspeptics had WL5 < 300 ml compared with 46 subjects with WL5 >=  300 ml. The groups did not differ with respect to sex, although there were more females in the WL5 < 300 ml group (83% vs. 71%; P = 0.2209). The groups likewise did not differ in age (t = 0.2655; P = 0.7912). The WL5 < 300 ml group contained significantly fewer abnormal EGGs than the WL5 >=  300 ml group (30% vs. 55%; P = 0.0279). No differences existed between the two groups for Tlag (t = 1.569; P = 0.1241) or T1/2 (t = 1.650; P = 0.1061).

                              
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Table 1.   Characteristics of functional dyspeptics achieving satiety at <300 ml or >300 ml

NDI scores did not differ significantly between the two groups (t = 1.622; P = 0.1092). Quality of life, however, was worse in the WL5 < 300 ml group, and PGWB scores were significantly lower (44.29 ± 21.94 vs. 59.09 ± 21.75; t = 2.979; P = 0.0039). Significant differences were seen for all PGWB subscales with the exception of vitality. Significant differences also existed between WL5 < 300 ml and WL5 >=  300 ml on the physical composite score of the SF-36 but not for the mental composite score. For the SF-36 subscales, significant differences were seen for social functioning and mental health with the WL5 < 300 ml, demonstrating greater impairment. No differences were seen between these two groups on the SCL-90 either with respect to total score or any subscale score.

Patients with FD were unable to accurately estimate drinking capacity (Fig. 7). Thirty-five patients with FD completed the unitless visual analog scale estimate of drinking capacity. The correlation between visual analog scale score and actual ingested volume was 0.2060 (P = 0.2351). Controls, however, were able to reasonably predict drinking capacity (n = 22; r = 0.58; P = 0.0051). To better understand this observation, we also asked a group of patients with documented diabetic (n = 16) or idiopathic (n = 3) gastroparesis and a group of 13 patients with GERD to complete the visual analog scale assessment and drink test. Gastroparesis was defined as scintigraphic evidence of delayed gastric emptying along with documented gastric stasis as well as a dominant symptom of vomiting. GERD was defined as a dominant symptom of heartburn with endoscopy demonstrating hiatal hernia and/or esophagitis and a clinical response to acid suppressive therapy. The volume to fullness for both gastroparesis and GERD patients was less than for controls (288 ± 197 and 406 ± 142 ml, respectively), but they were also able to accurately predict drinking capacity. For gastroparesis the correlation was r = 0.56 (P = 0.0124), and for GERD the correlation was r = 0.74 (P = 0.0041).


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Fig. 7.   Drink test self-efficacy. Controls (A) and patients with either gastroparesis (B) or gastroesophageal reflux disease (GERD; C) are able to accurately estimate drinking capacity, whereas functional dyspeptics (D) cannot. VAS, visual analog scale.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

In the present study we have demonstrated that, in healthy controls, WL5 is comparable with WL100 used by Boeckxstaens and colleagues (2, 3). Our WL5 values for both controls and dyspeptics agree quite well with those reported by Koch et al. (15). An advantage of WL5 over WL100 is that it can be administered in less time. With an average ingested volume of 1,128 ml administered at 100 ml/min, the WL100 method requires slightly more than 10 min to complete, which is twice as long as WL5. WL5 results in controls may not be repeatable over time. Test-retest values for healthy controls studied at least 2 wk apart were highly correlated, although volumes consumed at the second session were somewhat lower than initial volumes. Correlation between initial WL5 volumes and volumes at a third session at least 2 mo later were not correlated, however. These data suggest that drink tests are prone to the intrasubject variation seen with other measures of gastric function, particularly with respect to handling of liquids (17, 23).

In contrast to Boeckxstaens et al. (2, 3) who found a significant correlation between the Nutridrink test and the WL100 method, we did not find a correlation between WL5 and LM. Certainly the use of caloric-based drinks introduces a variety of additional factors influencing satiety, including caloric composition, osmolarity, and palatability of the test meal. Although in certain situations the use of caloric meals might be useful, water would seem to offer a modality that restricts satiety determinants to gastric distension, visceral sensitivity, and psychological determinants of fullness.

No healthy control consumed <300 ml of water. We therefore defined an abnormal drink test as the ingestion of <300 ml using the WL5 method. With the use of this definition, 47% of FD subjects had impaired drinking capacity. This is consistent with observations made by other investigators (3, 15, 34). No correlation was found in healthy subjects or dyspeptics with respect to drink test volume and T1/2 for solid-phase gastric emptying. A modest but significant correlation was seen in dyspeptics for drink test volume and Tlag, but Tlag values did not differ significantly between WL5 < 300 ml and WL5 > 300 ml groups.

An abnormal EGG was seen in 45% of FD subjects, which is consistent with previously published observations (15, 18, 22). Significantly fewer FD subjects with abnormal drink tests also had abnormal EGGs. The EGG and gastric emptying data would suggest that an abnormal drink test in FD patients is not a marker for disturbed gastric emptying or myoelectrical activity.

Additionally, recent studies using a barostat have shown a poor correlation between drink test volume and threshold to discomfort or fundic accommodation (3). This is not surprising. Barostat testing most commonly examines only the proximal stomach, whereas drink tests distend both the proximal and distal stomach (9). Since gastric emptying begins within minutes of ingestion, the proximal small bowel is also likely stimulated by the drink test (10). In addition to proximal stomach hypersensitivity, duodenal and antral hypersensitivity have also been demonstrated in FD subjects (4, 27). Because gut perception is influenced by spatial summation, the volume of distribution may be a critical determinant of subject response (28).

FD subjects were significantly more symptomatic than healthy subjects both at baseline and after the drink test. No correlations existed between volume to satiety and symptoms for controls or for FD subjects with respect to bloating and fullness. FD subjects displayed a significant negative correlation between volume to satiety and scores for nausea, suggesting that patients with dominant symptoms of nausea were less likely to drink.

FD subjects also had greater symptom severity as measured by NDI and lower quality of life on both SF-36 and PGWB measures. Psychopathology was significantly more prevalent among FD subjects, and significant differences existed between dyspeptics and controls for all SCL-90 subscales.

Among FD subjects, however, the drink test was not particularly helpful in delineating meaningful clinical subgroups. Across the FD population, there was little correlation between volume to fullness and measures of quality of life or psychopathology. There was a significant negative correlation between NDI scores and drink test volume, but this was modest. For SF-36, significant, modest positive correlations existed on the physical and social functioning subscales. Modest positive correlations were also seen on the interpersonal sensitivity and paranoid ideation subscales of the SCL-90. The significance of this observation is not clear, and this study was not designed to accurately identify personality characteristics of test subjects.

In contrast to correlations of WL5 with measured variables across the FD population, comparisons of FD subjects with normal and abnormal drink tests disclosed several significant differences between these groups. FD subjects with normal or abnormal drink tests did not differ significantly with respect to NDI scores, but the abnormal drink test group did have significantly lower PGWB scores as well as significantly lower SF-36 subscale scores for social functioning and mental health. SCL-90 scores were not different between the two groups. These data suggest that an abnormal drink test identifies subjects with greater impairment in quality of life.

The poor correlation between estimated and observed drinking capacity among dyspeptics was a surprising finding. If the FD subjects had a primary gastric abnormality that limited drinking capacity, one would logically expect them to not only drink less but to also anticipate the ability to drink less, as was seen in the patients with gastroparesis. These data support the concept of impaired visceral perception in dyspeptics. The FD subjects in this study seem uncertain as to exactly what their stomachs will allow them to accomplish.

In summary, WL5 is a simple measure that correlates well with other water-based drink tests but not with caloric-based methods. Intrasubject variability, at least in healthy controls, appears to be significant for WL5. An abnormal water load test, defined as the ingestion of <300 ml of water, is not a marker for abnormal gastric emptying or gastric myoelectrical activity. FD subjects with an abnormal drink test would appear to represent a clinical subset more likely to report nausea and with greater psychological distress and impairment of quality of life. Dyspeptics also appear less able to accurately predict drinking behavior compared with controls, gastroparetics, and patients with GERD. Whether this disturbance is caused by primary visceral pathology or more central mechanisms cannot be elucidated from these data.

Whether the water load test will emerge as a useful clinical tool remains to be determined. At present, insufficient evidence exists to support the routine use of the water load test in clinical practice. Available literature suggests that the test is not a surrogate for gastric emptying, accommodation, or visceral sensitivity. The water load test, originally intended to be a noninvasive measure of gastric physiology, may in fact be a better measure of personality characteristics and quality of life.


    FOOTNOTES

Address for reprint requests and other correspondence: M. P. Jones, 251 East Huron St., Galter Pavilion 4-104, Chicago, IL 60611-2908 (E-mail: mpjones{at}nmh.org).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

First published 15 January 2003;10.1152/ajpgi.00361.2002

Received 26 August 2002; accepted in final form 13 January 2003.


    REFERENCES
TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

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