13C Trioctanoate Breath Test as a Measurement of Gastric Fat Volume Emptying (13CTriOBT)

13C breath tests for the measurement of gastric emptying (GE) were first developed in the early 1990s. These tests have clear advantages over many other GE imaging techniques as they are relatively inexpensive, simple to use, can be carried out in children and pregnant women or those who have contraindications to MRI. Therefore these tests have been used in a variety of clinical settings such as in the assessment of gastroparesis or delayed GE in diabetic patients or the assessment of GE with fat containing enteral formulas in critically ill patients. Breath tests rely upon the ingestion of a 13C stable isotope markers such as the medium chain fatty acid 13C octanoic acid (OCC) and the tryglyceride13C trioctanoate (TriOCC).

However, 13C breath tests are an indirect measure of GE. Thus, GE data acquired from breath tests are a result of numerous complex interactions which include: 1) the chemical properties of markers and their interactions with test meals during gastric processing 2) absorption from the duodenum, 3) metabolism by the liver (oxidation of fatty acids) and 4) final excretion as 13CO2 by the lungs. All of these complex interactions can become compounded when the gastric processing of lipid emulsions (LEs) are investigated and thus careful consideration and selection of breath test markers is required.

The investigators have developed isocaloric and isovolume LEs with different GE properties as shown previously with MRI. The acid stable (LE1) and acid unstable lipid emulsion (LE4) responds differently to the conditions within the stomach. LE1 empties relatively uniformly from the stomach. However, the LE4 separates into water and high fat phases after 15-30 min of being in the stomach. In the late phase of GE the emulsion is re-emulsified and thus there are three distinct GE phases in LE4. Once separation of LE4 occurs the aqueous and low fat phase empties fairly rapidly from the stomach whereas the second fat phase empties more slowly. The differing GE pattern of acid unstable LEs has a profound effect on GE breath test data dependent upon the selection of the breath test marker used.The investigators have previously demonstrated that the OCC breath test (OBT) is an inappropriate measure of the gastric emptying of fat as the OBT is influenced by 1) Post gastric processing of the OCC marker and 2) its interaction with the physical form and concentration of the fat present in the stomach and duodenum. These effects were highlighted by only a marginal concordance agreement with the OBT half emptying (T50) of 13CO2 recovery and fat volume T50 (MRI T50) with LE1 and no agreement with LE4 (rc=0.7 and rc=0.4 respectively)..

The main aim of this study is to investigate whether TriOCC is a more appropriate breath test marker to use in the measurement of the GE of fat. As the TriOCC is a triglyceride it has similar physiochemical properties to nutritional lipids. Therefore, it is more likely to behave similarly in the gastric and duodenal environment to ingested lipids in emulsions such as rapeseed oil. In study 1 the investigators will compare the breath test markers TriOCC and OCC in LE1. In a sub set of participants a validated MRI quantitative fat fraction method will be used to determine reference values for the half gastric emptying time of fat (MRI T50). This will be correlated to half emptying (T50) of 13CO2 recovery generated from percentage dose recovery per hour (PDR/h) curves. The interim analysis will assess whether the TriOCC is more related to gastric fat volume emptying than the OCC marker in LE1. Should TriOCC be representative of gastric fat volume emptying study 2 will then proceed. Study 2 will then assess the gastric emptying of fat as above but with LE4.

A secondary aim is to develop an algorithm to quantify the heterogeneity of fat distribution within gastric content for MRI data. The gastric processing of lipid emulsions as visualized by MRI has been shown to result in a large inter individual variation of fat distribution. By quantifying this heterogeneity we aim to determine the degree of flocculation and creaming of the emulsions across the length of the stomach.