ZAGREB, 2 Feb 2022 - Slobodan Vukičević, a member of the Croatian Academy of Sciences and Arts (HAZU), and his associates have discovered a new therapy for acute myocardial infarction and published an article in the prestigious scientific journal Nature Communications, HAZU announced in a statement on Wednesday.
The research on the prevention of fibrosis in a model of acute myocardial infarction was carried out at the Laboratory for Mineralised Tissues of the University of Zagreb School of Medicine, and the International Centre for Genetic Engineering and Biotechnology in Trieste.
The results have shown the therapeutic effect of BMP1.3 antibodies in preventing cardiomyocyte apoptosis, reducing the formation of scar tissue and preserving the cardiac function after myocardial infarction in rodents.
Acute myocardial infarction is one of the most common causes of death today, and none of the therapies proposed so far is based on the use of antibodies. The starting point for the research was the discovery of an elevated level of BMP1.3 antibodies in the blood of patients who have suffered myocardial infarction, the statement said.
The article was chosen among the 50 best articles published in Nature Communications in the last 24 months.
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June 10, 2021 - Do you ever wonder how life was formed? Always dedicated to scientific progress, the Ruđer Bošković Institute chemist team made progress in life formation research supporting the theory that the first molecules needed to develop life were formed on the surfaces of minerals in pre-historic times.
Science explores our present reality, but also the past. With many knowledge or credible theories on evolution, the very basic questions such as „how life came to form“, remain unclear. But why?
„Given that condensation (the process of water vapor turning back into liquid) of free amino acids is thermodynamically unfavoruable process in the water medium, it is a great mystery how it came to the formation of peptides before life on earth“, states the Ruđer Bošković Institute (IRB) press release.
It's worth noting that the thermodynamically unfavourabale process means the process is irreversible, which means it can't be reconstructed, and that's why scientists can see the formation of peptides, chains that connect amino acids that are crucial for life.
So, meet prebiotic chemistry – a study of chemistry dedicated to address and discover how organic compounds formed and self-organized for the origin of life, but so far without consensus.
But, progress is made once again thanks to the always active IRB. IRB's chemist team (José G. Hernández, dr Krunoslav Užarević, and Ph.D. student Tomislav Stolar,), in collaboration with colleagues from the pharmaceutical company Xellia (dr. sc. Ernest Meštrović, mag. chem. Saša Grubešić and dr. Nikolaom Cindro from the chemical department at the Faculty of Science (PMF), University of Zagreb), showed that with mechanochemical activation in a solid-state, the amino acids (organic compounds that combine to form proteins, with both being considered „the building blocks of life“) - such as glycine or alanine form peptides on mineral surfaces.
This supports the theory that life molecules could've been formed on Earth's mineral surfaces. The paper titled „Mechanochemical Prebiotic Peptide Bond Formation“, published in the prestigious Angewandte Chemie scientific journal published on behalf of the German Chemical Society presents these findings in greater detail.
Stolar, Užarević and Hernandez © Ruđer Bošković Institute
„In this research, we showed that mechanochemical activation of free glycin ground with ball mill allows the new oligomers (molecules made of few similar or identical repeating units) by adding minerals that are basic components of earth surface and meteorites. With the identification of organic and inorganic molecules present in the Solar system, it's important in laboratory conditions to develop suitable processes that would explain the presence of these molecules. Such fundamental knowledge can then be applied in modern synthetical chemistry“, said a member of the IRB chemist team Tomislav Stolar. Stolar also participated in developing a new material known as CuZn-MOF-74 on which TCN previously wrote about.
The research was financed by the Croatian Science Foundation (HRZZ), and the next step is to apply this knowledge to synthesize new chemicals, which was one of the purposes of the research described by HRZZ.
IRB adds that the fact that various geological processes change the earth's surface, there is no historic evidence that could definitely answer how life on Earth was formed. It is believed that the first simple molecules triggered complex molecules to form in a process called chemical evolution and from that, life further continued to develop. Liquids, solid surfaces, or the phases between the two could've been potential conditions for these reactions, and mechanical energy sources were most likely found in meteor strikes, erosion, earthquakes, and more while thermal energy was most likely supplied by geothermal sources.
Learn more about Croatian inventions & discoveries: from Tesla to Rimac on our TC page.
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May 5, 2021 - With ecology being the key to survival, the Ruđer Bošković Science Institute combats climate change by developing a new material known as CuZn-MOF-74.
The pandemic is nasty, the nuclear holocaust is a scary thought, but greenhouse gases remain an omnipresent potential for the death of us as they trigger climate change on whose negative effects scientists have been warning us about for decades.
Like the United States, the Environmental Protection Agency informs on its website, these gases trap the heat in the atmosphere, which in terms raises the temperature we experience.
The website lists the main types of these airier troublemakers:
CO2 (Carbon dioxide - enters the atmosphere through burning fossil fuels (coal, natural gas, and oil), solid waste, trees, and other biological materials, and also as a result of certain chemical reactions. It is removed by plants that use it for photosynthesis – a process that provides food for the pants and oxygen for other beings).
CH4 (Methane-emitted during the production and transport of coal, natural gas, and oil. Methane emissions also result from livestock and other agricultural practices, land use, and the decay of organic waste in municipal solid waste landfills).
N2O (Nitrous oxide - emitted during agricultural, land use, industrial activities, combustion of fossil fuels and solid waste, as well as during treatment of wastewater).
Last but not least:
Fluorinated gases ( such as Hydrofluorocarbons, perfluorocarbons, sulfur hexafluoride, and nitrogen trifluoride are synthetic, powerful greenhouse gases that are emitted from a variety of industrial processes. Fluorinated gases are sometimes used as substitutes for stratospheric ozone-depleting substances. These gases are typically emitted in smaller quantities, but because they are potent greenhouse gases, they are sometimes referred to as High Global Warming Potential gases)
Each of these gases can stay in the atmosphere for a very long time, and transferring these gases into something else is a challenge to beat. Fortunately, at least for carbon dioxide, we might be getting closer to the solution than we think.
Pixabay
Ruđer Bošković Science Institute (IRB) in Croatia reported on its website that they are at the brink of a new material that can selectively transform carbon dioxide into methanol alcohol. The green chemists in Zagreb were closely cooperating with colleagues from the Slovenian Chemical Institute (KI), and McGill University in Canada. The results of their mutual research, in a more further scientific detail, are published in a scientific article on the prestigious ACS Publications.
But in the summarization, doctoral candidates Tomislav Stolar and Valentina Martinez, alongside dr. Bahar Karadeniz, under the lead of dr. Krunoslav Užarević (IRB), and dr Tomislav Friščić (McGill University) developed a bi-metal proposal coordination material known as CuZn-MOF-74. The layman speaking complex name is owned to the fact it's made from copper (Cu) and zinc (Zn) using a mechanic-chemical method of making bi-metal metalorganic networks known as MOF-74. As TCN previously reported, that method is an environmentally sustainable synthetic strategy that is further elaborated in a scientific article in 2019.
The catalytical properties of this material were tested KI in Ljubljana with the help of the scientists from the Institute: dr. Blaž Likozar, dr. Gregor Mali, dr. Ana Bjalić, and Anže Prašnikar.
The results have shown that this material has a modest catalyst (meaning it speeds up) activity to synthesize methanol, and post-reaction presented the scientists with a non-porous material which showed multiple enhancement of both catalyzation and selection for methanol synthetization.
„This research is a good example of multidisciplinary and international collaboration between strong research centers in the region. To me, as a young scientist, it's important that I can work on the current issues, such as transforming carbon dioxide into methanol, thanks to the guidance of dr. Užarević. There is a big potential for switching to sustainable chemical processes through the program of European Green plan, and research in that field should be the priority“, said the lead author Tomislav Stolar, a doctoral candidate in the IRB's laboratory for green synthesis.
The IRB official website added that the search for an effective catalyzation to transform carbon dioxide into methanol is the focus of scientists worldwide. Methanol could also be then used as a fuel and replace the current fossil products.
Today you already have the term „Methanol Economy“ that predicts methanol will impose as the vital compound to store energy, as a fuel, and a source of carbon to synthesize valuable compounds. Efficient synthesis of methanol from carbon dioxide presents an example of sustainable chemical reaction of added value, and with great economic potential“, concludes the press release on IRB.
Apart from IRB scientists combating climate change, Croatia takes care of the environment, particularly national parks on whom you can learn more on our TC page.
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