T ₁ and T ₂ relaxation times

T ₁ and T ₂ relaxation times reflect how protons in a magnetic field relax back to their equilibrium position after excitation by an RF pulse. The main applications of T ₁ and T ₂ are based on the investigation of the relaxation behaviour of water protons in different environments^{(Reference Mariette42)}. Water proton relaxation is mainly determined by their mobility and is affected by macromolecular composition and structure. T ₁ and T ₂ measurements have been used to study various food properties such as moisture content, food structure and macromolecule concentration^{(Reference Kirtil, Cikrikci and McCarthy43)}. For instance, Ziegler et al.^{(Reference Ziegler, MacMillan and Balcom44)} used T ₁ measurements to predict water migration in starch-pectin gels during drying since T ₁ decreases with the decrease of their moisture content. T ₂ was used to predict water-holding capacity of whey protein particles; a higher water-holding capacity is associated with a longer T ₂. Similarly, T ₂ has been used to study the swelling of hydrogels^{(Reference Ozel, Uguz and Kilercioglu45,Reference Peters, Vergeldt and Van As46)} . T ₂ has also been used to study the local structure of cheese; due to the inhomogeneity of the cheese, three distinct T ₂ relaxation components could be identified reflecting serum water (the water accumulated in the protein network), the water inside meshes of the casein gel-like network, and the water trapped within the casein matrix^{(Reference Gianferri, D'Aiuto and Curini47)}. In addition, T ₂ can be used to determine the protein concentration in casein solutions; with increasing concentration the T ₂ decreases^{(Reference Le Dean, Mariette and Marin48)}. These examples show that T ₁ and T ₂ can be used to monitor changes in water migration, food structure and the composition of food and digestive juice that take place during digestion^{(Reference Bornhorst6)}. Despite this, T ₁ and T ₂ measurements have only been applied in a limited number of digestion studies. For instance, T ₂ has been shown to be useful in detecting penetration of digestion fluid into the food matrix during in vitro digestion^{(Reference Bordoni, Picone and Babini33,Reference Bordoni, Laghi and Babini49)} . Another study showed a linear association between viscosity of locust bean gum meal and T ₂ in vitro, and highlighted the possible application of T ₂ to monitor changes in meal viscosity in the gastric lumen in vivo with the use of MRI^{(Reference Marciani, Manoj and Hills50)}. Moreover, in our recent study we show that the hydrolysis of protein during in vitro gastric digestion can be monitored by T ₂; T ₂ was associated with protein released from food particles into the surrounding liquid^{(Reference Deng, Janssen and Vergeldt51)}. However, in vivo gastric digestion is more complicated than the static in vitro model used here, which e.g. does not take into account dynamic processes such as the production of gastric juice and GE. These processes will introduce changes in the system that have multiple effects such as pH changes and dilution, in addition to the hydrolysis of nutrients. Because T ₁ and T ₂ are affected by many such factors, careful validation is needed to be able to interpret changes in T ₁ and T ₂ in different digestion contexts. This requires further investigation under dynamic circumstances, both in vitro and in vivo and the combination of NMR and MRI T ₁ and T ₂ measurements. For example, as shown in Fig. 2, the NMR T ₂ spectrum shows separate peaks that represent the protein gel and the simulated gastric fluid around it. This information contributes to the interpretation of the MRI T ₂ maps.

Fig. 2. (Colour online) Illustration of how NMR and MRI of the same in vitro model can be used to study the dependence of magnetic resonance parameters on nutrient breakdown. Shown here is the increase in T ₂ relaxation rate (R ₂ = 1/T ₂), measured with either technique, and the protein fraction in simulated gastric juice (SGF) during digestion of whey protein gel pieces. Adapted from Deng et al.^{(Reference Deng, Janssen and Vergeldt51)}.

T _1ρ

Another relaxation time of interest in MR is the T _1ρ or the T ₁ relaxation time in the rotating frame. T _1ρ is useful to study low-frequency motion processes and chemical exchange in biological tissues. It is measured by applying an additional RF pulse after the excitation pulse to lock the magnetisation in the rotating frame. The time it takes for the locked magnetisation to decay to zero is the T _1ρ relaxation time^{(Reference Wáng, Zhang and Li52)}_. In addition to conventional relaxation time measurements, T ₂ and T _1ρ relaxation time dispersion measurements^{(Reference Palmer53)} are promising MR markers for monitoring digestion because they can be used to examine macromolecules in solution or the interaction between bulk water protons and exchangeable macromolecule protons in semi-solids. In relaxation time dispersion measurements, the relaxation time is measured under varying measurement conditions. In the presence of chemical exchange, for example proton exchange between a macromolecule and bulk water, a dispersion of the relaxation time under those varying conditions can be observed. The extent of dispersion depends on the rate of chemical exchange. Compared to conventional relaxation time measurements, relaxation dispersion is more quantitative, since the experimental data can be fitted with theoretical models of two- or three-site exchange from which the exchange rate can be extracted^{(Reference Wáng, Zhang and Li52,Reference Ishima54,Reference Ishima and Bagby55)} . This exchange rate depends on the state of a macromolecule, e.g. intact or digested, and hence, can potentially be related to the kinetics of digestion. However, to date the application of T ₂ dispersion has been limited to investigating molecular dynamics of proteins in vitro ^{(Reference Hansen, Lundström and Velyvis56)}. T _1ρ dispersion, in contrast, has been more commonly applied in in vivo MRI studies, but not yet in the domain of digestion. Duvvuri et al.^{(Reference Duvvuri, Reddy and Patel57)} suggested that in cartilage proton exchange between protons from NH and OH groups in the proteoglycans and water dominate the T _1ρ dispersion of water. They showed that the exchange rates increase with proteoglycan breakdown. This suggests that T _1ρ dispersion has potential as a marker for in vivo monitoring of protein digestion.

In conclusion, MR relaxation parameters and their meaning in a digestion context need to be further elucidated. NMR can aid the interpretation of in vitro and in vivo relaxometry measurements with MRI. In turn, in vivo MRI can serve to validate and inform in vitro models.

Magnetisation transfer

Magnetisation transfer (MT) is an MR technique that is used to create a contrast between tissues in which protons are present in three different states: (i) in free water, (ii) bound to semi-solid macromolecules and (iii) as water in the hydration layer between the macromolecules and free water. In an MT measurement, the magnetisation of macromolecular protons is saturated by application of an RF pulse. The saturation is then transferred to protons in water through proton exchange resulting in a decrease in the water signal intensity. The MT rate is sensitive to the formation of a semi-solid structure^{(Reference Henkelman, Stanisz and Graham58)} and hence could serve as a marker for the degree of coagulation of proteins during gastric digestion. The degree of coagulation can affect digestion and GE rate^{(Reference Ye, Liu and Cui59)}.

Chemical exchange saturation transfer

Chemical exchange saturation transfer (CEST) is a relatively novel MR technique. Its principle is similar to that of MT where saturated protons are exchanged with non-saturated protons in water. However, the main difference is that in CEST, saturation transfer takes place between a (macro)molecule in solution and water and that the saturation is frequency-selective^{(Reference Van Zijl and Yadav60)}. Dona et al.^{(Reference Dona, Pages and Gilbert41)} showed that CEST can be used to monitor the in vitro enzymatic degradation of macromolecular starch granules. Moreover, from their CEST measurement, the kinetics of glucose release during the enzymatic hydrolysis of cooked starch was successfully monitored, demonstrating the potential of CEST for obtaining quantitative information on food digestion^{(Reference Dona, Pages and Gilbert41)}. Longo et al.^{(Reference Longo, di Gregorio and Abategiovanni61)} used CEST to monitor the aggregation of bovine serum albumin during heat treatment and its subsequent hydrolysis by a protease in vitro. During heat treatment the proteins aggregate, thereby decreasing the accessibility of the protein protons for exchange with water protons. However, after digestion of the heat-treated protein, the protons become accessible for exchange again, resulting in an increase in saturation transfer. This suggests that CEST can serve as a marker for monitoring protein digestion and how this is affected by heat treatments. Another interesting application of CEST is pH imaging in which the endogenous amide proton transfer rate is related to the pH in the tissue of interest^{(Reference Pavuluri and McMahon62)}. Most applications of CEST pH imaging are done in the brain^{(Reference Zhou, Payen and Wilson63–Reference Consolino, Anemone and Capozza65)} where the pH is between 6⋅5 and 8⋅5. It would be of great utility if CEST could be used to make 3-D stomach pH maps since pH is an important factor that among others influences pepsin activity. However, stomach pH is between 1⋅5 and 3⋅5 in children or adults and between 3⋅5 and 5⋅5 in infants. This renders stomach pH imaging challenging due to the slower amide proton transfer rate at low pH.

Magnetic resonance relaxometry and cross-relaxation outlook

While NMR/MRI relaxometry and cross-relaxation techniques have not been applied much in food digestion research, the applications to date suggest that they have potential for monitoring digestion. For in vitro studies, it is possible to obtain quantitative information, such as the proton exchange rate from relaxation time dispersion, MT or CEST data by fitting with biophysical models of two- or three-site chemical exchange. The chemical exchange rate is expected to depend on the pH, macromolecular concentration and semi-solid fraction, which are all factors that change during digestion. However, reliable modelling of such data can only be done on sufficiently large data sets. The collection of such data sets is time-consuming and limited to in vitro studies. The main challenge lies in optimising experimental conditions such as the measurement time, size of datasets and sub-set of fitting parameters to enable quantitative application of the same measurements in vivo. Moreover, in vivo data acquisition has practical constraints and interpretation is harder. There are limits to the time that volunteers can spend in the scanner and scans have to be made during breath hold or with respiratory triggering minimise image artefacts caused by breathing movements. Physiological noise and constraints on acquisition times will result in poorer data quality compared to in vitro data. However, these are common challenges for any in vivo application of MRI, and there is continuing technical development aimed at ameliorating these issues. Moreover, as pointed out before, careful in vitro validation experiments can be used in the development and validation of these promising MR markers of digestion.

Layering and fat quantification

In the case of layer formation (phase separation), the different layers can simply be quantified on an MRI image. For example, when a more fatty layer forms this appears darker on a T ₂-weighted gastric MRI image than a more watery layer, see e.g.^{(Reference Camps, Mars and de Graaf78)}. Similarly, in the first hour after consumption breakfast porridges showed clear phase separation, with a brighter layer on top, consistent with a more liquid phase in the type of moderately T ₂-weighted MRI images made, and a darker layer at the bottom, consistent with thicker or more particulate material^{(Reference Alyami, Whitehouse and Yakubov83)}.

So far, we have mainly discussed volume measurements of different food fractions. However, after careful in vitro validation quantitative MRI measurements can be performed in vivo. For example, Marciani et al. investigated the dilution of polysaccharide test meals by gastric secretions^{(Reference Marciani, Gowland and Spiller70)} by exploiting the association between the T ₂ relaxation time (T ₂) and polysaccharide concentration^{(Reference Marciani, Manoj and Hills50)}. MRI is also well-suited to distinguish water and fat. Kunz et al.^{(Reference Kunz, Feinle-Bisset and Faas84)} specifically measured the fat component of a pasta meal (mayonnaise). By first assessing in vitro samples in which the fat concentration was varied they were able to calibrate their in vivo MRI measurements. Liu et al.^{(Reference Liu, Parker and Curcic85)} studied gastric and duodenal fat emptying and emulsion processing (creaming and phase separation) using fat emulsions that were administered through a nasogastric tube. They not only calibrated their fat quantification approach with in vitro MRI, but they also took gastric aspirate samples for further validation in vivo. The resulting fat fraction maps and intragastric emulsion profiles showed details of intraluminal phase separation and creaming that were not (well) visible on the conventional MRI images^{(Reference Liu, Parker and Curcic85)}. This approach was taken further by Scheuble et al.^{(Reference Scheuble, Schaffner and Schumacher86)} who studied the gastric behaviour of fat emulsions stabilised by three different biopolymers in vitro as well as in vivo with MRI, combined with blood sampling for measurement of TAG and cholecystokinin concentrations. These studies on fat digestion showcase that MRI can bridge the gap between in vitro digestion models and in vivo behaviour by carefully combining different types of measurements.

Coagulation

While eventual breakdown of structure is necessary to allow for GE, gastric conditions can also induce changes in the texture of the chyme such as gelling and coagulation. Since this involves the transformation from liquid to (semi-)solid it could slow GE. While coagulation will be readily visible on conventional stomach MRI images (see Fig. 3) it has hardly been systematically quantified. Coletta et al.^{(Reference Coletta, Gates and Marciani87)} looked at GE of breads with different gluten contents and additionally visually categorised the degree of heterogeneity of the food bolus in the stomach on MRI scans. They found that gluten did not change GE, although it made the chyme more heterogeneous. Also, there were no differences between the breads in gastrointestinal symptoms, postprandial small bowel water content, colonic volume and gas content measured with MRI. Another example is milk protein coagulation; protein digestion is strongly affected by pH changes in the stomach and the associated activity of pepsin. Digestion by pepsin as well as the pH decline over time cause the caseins in milk to coagulate as demonstrated in vitro ^{(Reference van Aken, Bomhof and Zoet88–Reference Ye, Cui and Dalgleish90)}, while the whey protein remains soluble. Casein coagulation is believed to slow down GE; the stomach empties only particles into the small intestine if they have a size of 1–2 mm^{(Reference Kong and Singh91)}. This notion is supported by in vivo studies showing that amino acids from whey protein appear faster in the blood than those from casein^{(Reference Boirie, Dangin and Gachon92,Reference Mahé, Roos and Benamouzig93)} . In vitro data also show that casein coagulation is affected by several factors such as processing-induced protein modifications, product composition such as mineral composition, and variations in gastric acidification and protease secretion^{(Reference Mulet-Cabero, Mackie and Wilde94,Reference Wang, Ye and Lin95)} . In addition, the source of the protein may influence gastric coagulation^{(Reference Hodgkinson, Wallace and Boggs96)}. However, these findings require verification in vivo. This would benefit from accurate quantification of chyme structure changes. Although visual grading is a useful and relatively simple approach, this could be taken further by validating the use of image texture metrics that can capture the observed heterogeneity; this may provide a more sensitive and objective assessment and information on what a certain degree of heterogeneity in an MRI image reflects in terms of particle sizes and texture attributes of coagulates. Such food matrix/chyme characteristics may influence gastric digestion and subsequent intestinal digestion and bioavailability (see e.g. Fardet et al.^{(Reference Fardet, Dupont and Rioux97)}).

Fig. 3. Examples of T ₂-weighted magnetic resonance images showing cross-sections through an empty stomach after an overnight fast (baseline) and after 250 ml milk consumption. At t = 3 min the gallbladder (gb) is clearly visible, and the gastric contents visible at baseline can be seen on top of the milk. At t = 30 and 90 min milk protein coagulation can be observed.

Blood parameters

Although it is quite well possible to obtain blood samples from participants lying in an MRI scanner, not many studies have combined MRI of the digestive tract with blood sampling to assess hormone responses related to digestion and nutrient bioavailability (see e.g. Alyami et al.^{(Reference Alyami, Whitehouse and Yakubov83)} and Mackie et al.^{(Reference Mackie, Rafiee and Malcolm81)}). GE and more detailed MRI markers of digestion could be linked to in vivo nutrient bioavailability measures such as blood glucose, fatty acid and amino acid profiles. For example, in vitro work showing that GE rate affects protein digestion, amino acid absorption and subsequent whole body protein anabolism after a meal^{(Reference Mulet-Cabero, Torcello-Gómez and Saha98)} could be validated with such an approach. One current candidate MRI marker for measuring the breakdown of protein foods is the T ₂ of the surrounding gastric fluid^{(Reference Deng, Janssen and Vergeldt51)}, but as discussed earlier other MRI measures may also be of interest. Such studies would provide unprecedented detail on how food characteristics affect digestion and bioavailability and can inform optimised food design. For example, the effects of different protein sources and processing-induced protein modification on GE, protein digestion and amino acid absorption measured by MRI and amino acid absorption in the blood could be explored. Better understanding of the determinants of protein digestion can inform choices for or design of products that are easier digestible, which is beneficial for people who have trouble ingesting enough protein, such as older adults, athletes and critically ill.