National University of Science and Technology MISIS researchers together with scientists from the Laboratory of Neutron Physics JINR conducted studies of biocompatible polymer materials used in endoprostheses, as well as advanced carbon composites at the Xeuss 3.0
NUST MISIS specialists use Xeuss 3.0 to analyse the crystal and molecular structure of new materials being developed. According to the Head of the Department of Physical Chemistry of NUST MISIS, Deputy Head of the “Luch” Laboratory, Candidate of Physics and Mathematics Alexey Salimon, it is the small angle
In order to provide the necessary set of properties of the created material, it is important to form its structure correctly. The next stage is the testing, in particular, in the case of implantology, special biological tests. “It is always a labor-intensive process of moving in the circle ‘structural studies — properties testing — application’. Researchers have to circulate in it for a long time in order to refine the task and improve the characteristics of the material,” the scientist said.
“Xeuss is a unique tool used specifically for structural research,” he noted. Alexey Salimon explained that his scientific group was motivated to work on Xeuss by such an advantage as a small illumination spot, i. e. the region of interest under study in the material volume. “This instrument has a very sharp focus with an illumination spot size on the sample of no more than
100-150 microns. You will not get such a resolution capability on most laboratory X—ray sources,” the scientist added. Sharp focus is important because it allows studying the peculiarities of strain distribution, in particular, when loading complex porous structures of carbon composite materials.It is known that synchrotrons provide the strongest
X-ray focus, but these are high-class and expensive instruments, and there are few of them in the world. “Modern laboratory instruments of the Xeuss class approach synchrotrons in a number of properties in the complex. This is a good possibility to fill the gap between extremely expensive megascience class instruments and traditional laboratory ones,” Alexey Salimon said.
A special frame testing device was created to simulate the mechanical loads of carbon composite samples. A small beam cut out of carbon composite is fixed in the device between two stops and, having installed Xeuss in the working chamber, loaded by pushing the stops against each other. As a result, it is possible to track in real time how the rupture occurs, what pressure must be applied, and how it correlates with the internal structure.
The innovative material for endoprostheses based on ultra-high-molecular-weight polyethylene (UHMWPE) combines three layers: solid, imitating smooth cartilage, porous UHMWPE, imitating sponge-like bone tissue, and porous collagen. It is very difficult to reproduce exactly the complex tissues of the human body. That is why composite and hybrid materials in bioengineering are the most common solution.
“Our materials for hip and knee joints are at the stage of preclinical development. A unique property of polymers is used in the endoprothesis of a hip joint, a low friction coefficient and high abrasion resistance,” Alexey Salimon highlighted. He told that the developed material makes it possible to carry out work both on the creation of artificial joints and on the reconstruction of the bones themselves. In the case of cancer, in order to save a limb, it is possible to replace large fragments of the thigh bone or shinbone of the leg, ulna, humerus bones of the arm, and other large bones. The “Bioengineering” Research and Education Centre at MISIS showed this in veterinary medicine, in operations on pets. It is much easier to obtain permission to use the material in surgeries on animals, just a signature from the owner, consent to use the innovative solution is enough.
Ultra-high-molecular-weight polyethylene has been used in surgery for a long time. “We are expanding and improving the standard types of such polymers and giving them special properties. In particular, for the hip joint cup, NUST MISIS was able to significantly reduce the friction coefficient and increase abrasion resistance through the use of carbon nanotubes,” the scientist said.
In addition to small-angle
Biocompatibility and other interesting properties of materials of the future are actively used in maxillofacial surgery. MISIS partners from the Research Institute of Emergency Pediatric Surgery and Traumatology use such materials in the tasks of reconstructing the cranial vault after craniocerebral trauma surgeries. “In the modern era, if brain edema begins after a traumatic brain injury, surgeons need to remove from a third to half of the area of the patient’s skull, which then has to be covered. And one of the solutions here is the use of a complex titanium-polymer structure, where the polymer is the one that we are developing,” Alexey Salimon said.
The work done was commented on by an FLNP senior researcher, Candidate of Physics and Mathematics Julia Gorshkova: “In 2022, the MISIS team and I conducted ‘targeting’ experiments on the topic of biocompatible polymer materials and advanced carbon composites on Xeuss 3.0. In fact, these were commissioning works on the facility. At this stage it was important for us to determine the limits of the device ourselves. The results obtained were impressive, and we included them in a joint publication1.” Julia Gorshkova said that on 15 February, Xeuss 3.0 facility was officially put into operation. “Today we already have plans to further develop mutually beneficial cooperation with the team of Professor Alexander Korsunsky on a regular basis. This is exactly the case when we have something to offer, and we have something to learn from our colleagues,” she said.
For reference
Xeuss 3.0 implements the method of small-angle (SAXS) and wide-angle (WAXS)
Other participants of the “Luch” collaboration include Skoltech, the Academician O. V. Roman Powder Metallurgy Institute (Belarus), Department of Electromagnetic Processes and Atomic Nuclei Interactions of the MSU Skobeltsyn Institute of Nuclear Physics, the Technological Institute of Superhard and Novel Carbon Materials (TISNCM), and the Laboratory of