Real time measurements of intestinal
gases: a novel method to study how food is being digested

Researchers in Wageningen (The
Netherlands), have been able to identify for the first time, how gut microorganisms
process different types of carbohydrates by measuring in real time the intestinal
gases of mice. This is not only a novel method to understand how food is
digested but could also tell us more about the role of gut microorganisms in
gut health.

Intestinal gases

The intestinal microbiota is a diverse and
dynamic community of microorganisms which regulate our health status. The
advancement of biomolecular techniques and bioinformatics nowadays allows
researchers to explore the residents of our intestines, revealing what type of microorganisms
are there. However, studying only the microbial composition of an individual
provides limited insights on the mechanisms by which microorganisms can
interact with the rest of our body. For example, far less is understood about
the contribution of the gut microorganisms in the production of intestinal
gases such as hydrogen, methane and carbon dioxide through the breakdown of
food and how these gases affect the biochemical pathways of our bodies.

Intestinal gases consist mostly of
nitrogen, and carbon dioxide, which originate primarily from inhaled air. Hydrogen
and methane though, are produced as by-products of carbohydrate fermentation
(break down), by intestinal microorganisms. However, not all carbohydrates are
digested in the same way. For instance, food with simple sugars can be rapidly absorbed
in the small intestine unlike complex carbohydrates such as fibers, which reach
the colon where they are digested by the colonic microbiota.

Lower_digestive_system

Measuring hydrogen in mouse intestines

To study these interactions and gain
knowledge on how microorganisms process carbohydrates, the research team led by Evert van
Schothorst from the Human and Animal Physiology Group of Wageningen University
(WU) in collaboration with the WU-Laboratory of Microbiology fed mice two
different diets with the same nutritional values but with different types of carbohydrates
(1). The first diet contained amylopectin,
a carbohydrate which can be digested readily in the small intestine while the
second diet contained amylose, a slowly digestible carbohydrate that is
digested by intestinal microorganisms in the colon.

Animals fed the easily digestible carbohydrates
showed minimal production of hydrogen whereas the group fed with the complex
carbohydrates presented high levels of hydrogen. Moreover, the two groups were
characterized not only by distinct microbial composition (different types of
bacteria present) but also distinct metabolic profiles (short chain fatty acids),
suggesting that the type of carbohydrate strongly affects microbial composition
and function.

The importance of
hydrogen

Hydrogen consumption is essential in any anoxic
(without oxygen) microbial environment to maintain fermentative processes. In
the intestine it can be utilised through three major pathways for the
production of acetate, methane and hydrogen sulphide. These molecules are
critical mediators of gut homeostasis, as acetate is the most predominant short
chain fatty acid produced in mammals with evidence suggesting a role in inflammation and obesity (2). Methane, which is produced by a specific type of microorganisms,
called archaea, has been associated with constipation related diseases, such as
irritable bowel syndrome(3) and also recently with athletes’ performance (4)! Finally hydrogen sulphide
is considered to be a toxic gas, although recent findings support the notion
that it also has neuroprotective effects in neurodegenerative disorders such as
Parkinson and Alzheimer diseases (5).

To the best of our knowledge, this is the first time that food-microbiota interactions have been studied continuously, non-invasively and in real time in a mouse model. Hydrogen is a critical molecule for intestinal health and understanding its dynamics can provide valuable information about intestinal function, and deviations in conditions such as Crohn’s disease or irritable bowel syndrome (IBS).

Further reading

1. Fernández-Calleja, J.M., et al., Non-invasive continuous real-time in vivo analysis of microbial
hydrogen production shows adaptation to fermentable carbohydrates in mice.

Scientific reports, 2018. 8(1): p.
15351.

https://www.nature.com/articles/s41598-018-33619-0

2.
Perry, R.J., et al., Acetate mediates a
microbiome–brain–β-cell axis to promote metabolic syndrome.
Nature, 2016. 534(7606): p. 213

3. Triantafyllou, K., C. Chang, and M. Pimentel,
Methanogens, methane and gastrointestinal
motility.
Journal of neurogastroenterology and motility, 2014. 20(1): p. 31.

4. Petersen, L.M., et al., Community characteristics of the gut microbiomes of competitive
cyclists.
Microbiome, 2017. 5(1):
p. 98.

5. Cakmak,
Y.O., Provotella‐derived hydrogen sulfide, constipation,
and neuroprotection in Parkinson’s disease. Movement Disorders, 2015. 30(8): p.
1151-1151.

Please share and like us:

What is inflammation?

Inflammation is the response of the body’s immune system against external factors that can put your health in danger. When this system feels it is attacked by something that may harm your health, it activates some molecules that are called cytokines in order to neutralize or avoid any damage so you can be safe.

Why is inflammation bad? What does it do?

Inflammation isn’t bad by itself, since its purpose is to protect our body. In some cases however, when the duration of this response is extended for too long- I’m talking about years- it can cause harmful effects to your health. Especially, it can affect the brain by active transport of cytokines throughout this organ.

Neuro-inflammation may occur if this process continues past early stages. Neuro-inflammation plays an important role in the development of mental diseases such as attention-deficit/hyperactivity disorder (ADHD), autism, schizophrenia, depression, anxiety, bipolar disorder (BD), and obsessive-compulsive disorder (OCD), where elevated levels of inflammation have been found(1).

What causes inflammation? 

Inflammation can occur by different factors. Some of them could be: pathogens, injuries, chronic stress, and diseases like dermatitis, cystitis or bronchitis to mention a few.

Nutritional factors like overweight and poor diet quality can also trigger this process by increasing fat accumulation in our cells and damaging them (2). The exact mechanisms that are involved in these processes are still in research.

What decreases inflammation?

Research has found that adhering to a healthy diet, like the Mediterranean diet, characterized by high intake of fruit, vegetables, whole grains, fish, lean meats and nuts, can decrease inflammation and protect you against depressive symptoms and anxiety (3,4).

There is evidence that prebiotics, probiotics and synbiotics (a combination of prebiotics and probiotics) can also help lowering inflammation. In addition, you should avoid eating pro-inflammatory foods that have been found to increase the risk of inflammation, and with it mental disorders. Some of these are refined carbohydrates, beverages with a lot of sugar added like soda, juice and sports drinks, processed meat and foods high in saturated fats (5).

What are anti-inflammatory foods

Anti-inflammatory foods are the contrast of pro-inflammatory foods. These are foods that have been found to promote or induce low levels of inflammation in our body, which may protect us against neurological disorders. Briefly, these foods include fruits, vegetables, olive oil, fish and spices like curcuma (turmeric).

Here’s what YOU can do to minimize inflammation and improve your mental health.

Inflammation and Foods

This was co-authored by Josep Antoni Ramos-Quiroga, MD PhD psychiatrist and Head of Department of Psychiatry at Hospital Universitari Vall d’Hebron in Barcelona, Spain. He is also professor at Universitat Autònoma de Barcelona.

Sources

  1. Mitchell RHB, Goldstein BI. Inflammation in children and adolescents with neuropsychiatric disorders: A systematic review. J Am Acad Child Adolesc Psychiatry [Internet]. Elsevier Inc; 2014;53(3):274–96. Available from: http://dx.doi.org/10.1016/j.jaac.2013.11.013
  2. Ogłodek EA, Just MJ. The Association between Inflammatory Markers (iNOS, HO-1, IL-33, MIP-1β) and Depression with and without Posttraumatic Stress Disorder. Pharmacol Reports [Internet]. 2018;70:1065–72. Available from: https://www.sciencedirect.com/science/article/abs/pii/S1734114017305923
  3. Lassale C, Batty GD, Baghdadli A, Jacka F, Sánchez-Villegas A, Kivimäki M, et al. Healthy dietary indices and risk of depressive outcomes: a systematic review and meta-analysis of observational studies. Mol Psychiatry [Internet]. Springer US; 2018;1. Available from: http://www.nature.com/articles/s41380-018-0237-8
  4. Phillips CM, Shivappa N, Hébert JR, Perry IJ. Dietary inflammatory index and mental health: A cross-sectional analysis of the relationship with depressive symptoms, anxiety and well-being in adults. Clin Nutr. 2017;37.
  5. Shivappa N, Bonaccio M, Hebert JR, Di Castelnuovo A, Costanzo S, Ruggiero E, et al. Association of proinflammatory diet with low-grade inflammation: results from the Moli-sani study. Nutrition. 2018;54:182–8.

 

 

 

Please share and like us: