Too little iron in the blood can lead to anemia and too much can signal problems with the immune system; German researchers have devised a promising new technique for detecting the amount of iron in the blood according to an Oct. 2, 2013 news item on ScienceDaily,
Lack of iron — caused by malnutrition — can lead to anemia while an increased level of iron may signal the presence of an acute inflammatory response. Therefore, the blood iron level is an important medical diagnostic agent. Researchers at Ulm University [Germany], led by experimental physicist Fedor Jelezko, theoretical physicist Martin Plenio and chemist Tanja Weil, have developed a novel biosensor for determination of iron content that is based on nanodiamonds.
Here’s an image of microscopic diamonds before they’ve been ground down to the nanoscale,
The Oct. 2, 2013 University of Ulm news release (on the Alpha Galileo Foundation website,) which originated the news item, describes the problem the scientists were addressing and their solution,
“Standard blood tests do not capture — as one might expect — free iron ions in the blood, because free iron is toxic and is therefore hardly detectable in blood,” explains Professor Tanja Weil, director of the Institute for Organic Chemistry III, University of Ulm. These methods are based on certain proteins instead that are responsible for the storage and transport of iron. One of these proteins is Ferritin that can contain up to 4,500 magnetic iron ions. Most standard tests are based on immunological techniques and estimate the iron concentration indirectly based on different markers. Results from different tests may however lead to inconsistent results in some clinical situations.
The Ulm scientists have developed a completely new approach to detect Ferritin. This required a combination of several new ideas. First, each ferritin-bound iron atom generates a magnetic field but as there are only 4,500 of them, the total magnetic field they generate is very small indeed and therefore hard to measure. This indeed, posed the second challenge for the team: to develop a method that is sufficiently sensitive to detect such weak magnetic fields. This they achieved by making use of a completely new, innovative technology based on tiny artificial diamonds of nanometer size. Crucially these diamonds are not perfect —colorless and transparent — but contain lattice defects which are optically active and thus provide the color of diamonds.
“These color centers allow us to measure the orientation of electron spins in external fields and thus measure their strength” explains Professor Fedor Jelezko, director of the Ulm Institute of Quantum Optics. Thirdly, the team had to find a way to adsorb ferritin on the surface of the diamond. “This we achieved with the help of electrostatic interactions between the tiny diamond particles and ferritin proteins,” adds Weil. Finally, “Theoretical modeling was essential to ensure that the signal measured is in fact consistent with the presence of ferritin and thus to validate the method,” states Martin Plenio, director of the Institute for Theoretical Physics. Future plans of the Ulm team include the precise determination of the number of ferritin proteins and the average iron load of individual proteins.
As the news release notes, this research is part of a larger project,
The demonstration of this innovative method, reported in Nano Letters [journal], represents a first step towards the goals of their recently awarded BioQ Synergy Grant. [10.3 million Euro which the scientists were awarded last December 2012 by the European Research Council] The focus of this project is the exploration of quantum properties in biology and the creation of self-organized diamond structures.
“Diamond sensors can thus be applied in biology and medicine,” say the Ulm scientists. But their new invention has its limits “. Whether the children have actually eaten their spinach cannot be detected with the diamond sensor, that’s still the prerogative of parents “, confesses quantum physicist Plenio
Here’s a link to and a citation for the paper,
Detection of a Few Metallo-Protein Molecules Using Color Centers in Nanodiamonds by A. Ermakova, G. Pramanik, J.-M. Cai, G. Algara-Siller, U. Kaiser, T. Weil, Y.-K. Tzeng, H. C. Chang, L. P. McGuinness, M. B. Plenio, B. Naydenov, and F. Jelezko. Nano Lett., 2013, 13 (7), pp 3305–3309 DOI: 10.1021/nl4015233 Publication Date (Web): June 5, 2013
Copyright © 2013 American Chemical Society
This paper is behind a paywall.