A novel form of iron for fortification of foods

Whey protein nanofibrils loaded with iron nanoparticles: ETH researchers are developing a new and highly effective way of fortifying iron into food and drinks.

Edible whey protein nanofibrils carrying iron nanoparticles (black dots) could eliminate iron deficiency in an efficient and inexpensive way. (TEM image: ETH Zurich/Yi Shen)
Edible whey protein nanofibrils carrying iron nanoparticles (black dots) could eliminate iron deficiency in an efficient and inexpensive way. (TEM image: ETH Zurich/Yi Shen)

Around 1.2 billion people worldwide suffer from iron deficiency, with women worse affected than men. In Europe, one in five women around the age of 20 suffers from iron deficiency. Typical symptoms include diminished work performance, fatigue, anaemia and headaches.

Boosting iron levels through the diet or supplements is tricky, as the iron must be in a form that the body is able to absorb successfully. Iron is also a trace element that can alter the colour, taste and smell of the food it is added to, making it far less appetising.

Combining protein fibres and iron nanoparticles

The two ETH professors Raffaele Mezzenga and Michael B. Zimmermann from the Department of Health Sciences and Technology have discovered a new way of fortifying food and drinks with iron: with a hybrid material made of edible whey protein nanofibrils and iron nanoparticles. The relevant study produced by Mezzenga’s doctoral student Yi Shen in collaboration with Zimmermann’s doctoral student Lidija Posavec has just been published in the journal Nature Nanotechnology.

The protein nanofibrils are formed by denaturing native whey protein by heating them to 90°C, and further hydrolysing them in strong acid until they form the final protein filaments. Several protein filaments then organise themselves into thicker protein nanofibrils.

The researchers combined these nanofibrils with iron nanoparticles which can be readily absorbed by the body. To produce these nanoparticles, the researchers mixed ferric chloride (FeCl3) directly with the protein nanofibrils in the same acid solution, creating iron nanoparticles of 20 nanometres which immediately bound to the protein nanofibrils surface and were effectively stabilised. This is a key trick, as normally iron nanoparticles are not stable: they tend to quickly clump together and form aggregates that cannot be easily mixed into foods or drinks.

Iron deficiency rapidly overcome

To test the efficacy of the new iron compound, scientists administered it to rats with iron deficiency after being fed a low-iron diet. The new preparation cured the animals’ iron deficiency and the associated anaemia just as effectively as iron sulphate (FeSO4), the most commonly-used iron supplement used in humans; FeSO4, however, often causes undesirable sensory changes in foods.

The new supplement was also easily digested. As the authors showed in an ad-hoc in-vitro experiment, the enzymes in the rats’ stomachs entirely digested the whey protein nanofibrils. In addition,  acid conditions like in the stomach dissolved the iron nanoparticles into iron ions, which can then be quickly absorbed into the blood and used to produce new red blood cells.

The iron-coated whey protein nanofibrils can be administered either in powder or liquid form, and the new compound can be easily added to different types of food without affecting their taste or smell or color.

No side-effects so far

To identify potential risks and side-effects, the researchers ran microscopic tests on the rats’ brain, heart, kidney and other organs, after they had eaten the nanofibrils for 2 weeks. They were particularly interested in the whey protein nanofibrils, which have never been used in foods or food supplements before. From a structural point of view, these structures are similar to amyloid fibrils, which accumulate in the brain and have been linked to Alzheimer’s disease, but differently from them, in the present case are made out of hydrolysed edible food proteins.

The ETH researchers therefore wanted to make sure that eventually undigested protein fibres in their iron supplement do not accumulate in the body and potentially produce tissue anomalies. “On examining the organs and tissues of the rats, we did not find any evidence of nanoparticles or nanofibrils accumulating or possibly causing organ changes”, says Mezzenga. One thing he can be sure of: “Our new iron supplement has enormous potential for successfully combating iron deficiency in an economic and efficient way”.

Alternative to existing products

The ingredients used to make this innovative food supplement are cheap and in plentiful supply. Whey proteins are a side-product of the dairy industry. Iron salts are also cheap and readily available. As both the process and the ingredients are easy to work with, this iron food supplement would also be a good alternative for people living in poor countries who are more prone to iron deficiency than those living in western industrialised nations.

The researchers have filed a patent for their new product and look forward discussing with commercial partners to develop the technology further.

This study was funded by the Swiss National Science Foundation as part of the National Research Programme external page NRP 69 Healthy Nutrition and Sustainable Food Production.

Reference

Shen Y, Posavec L, Bolisetty S, Hilty FM, Nystr?m G, Kohlbrecher J, Hilbe M, Rossi A, Baumgartner J, Zimmermann MB, Mezzenga R. Amyloid Fibril Systems Reduce, Stabilize and Deliver Bioavailable Nanosized Iron. Nature Nanotechnology, advance online publication 24th April 2017. DOI: external page 10.1038/nnano.2017.58

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