Researchers from Brazil and Germany have investigated how phytochemicals from papaya, passion fruit, and various medicinal plant extracts work at the molecular level. Their findings were presented during FAPESP Week in Germany, highlighting potential health benefits and therapeutic applications.
Fruits and plant extracts are rich in bioactive compounds that may help prevent or treat various diseases. To better understand how these compounds work, researchers from universities and institutions in Brazil and Germany have conducted separate but complementary studies.
Some of their findings were presented on March 25 during a lecture session on the future of food and nutrition research, held at the Free University of Berlin as part of FAPESP Week Germany.
Ulrich Dobrindt, a professor at the University of Munich, explained that medicinal plants contain diverse phytochemicals, naturally occurring chemical compounds, that can combat bacterial infections through different mechanisms. These compounds help strengthen the body’s immune response. As a result, there is growing interest in using plant extracts to prevent and treat urinary tract infections (UTIs), one of the most common infections globally, which are typically treated with antibiotics.
“Although their anti-inflammatory, antipyretic and analgesic effects are well known, the active compounds of these plants – such as flavonoids, alkaloids and terpenoids – and their mechanisms of action on pathogen cells have yet to be characterized. Some are antibacterial, but many don’t have this effect,” said the researcher.
Credit: Elton Alisson/Agência FAPESP
In order to further their understanding, German scientists have developed infection models to study the effects of plant extracts on the innate immune response and on the epigenetic regulation of gene expression (biochemical processes that activate and deactivate genes). In bladder cells, for example, they are studying the effect of traditional plants with urological activity, according to the German pharmacopoeia.
In collaboration with researchers at the Federal University of Minas Gerais (UFMG) in Brazil, it was found that some aqueous plant extracts (from species such as Solidago gigantea and Equiseti herba) significantly reduced the adhesion and survival of Escherichia coli in human bladder epithelial cells.
“We observed a drastic reduction in the adhesion and proliferation of this bacterium in bladder cells,” said Ulrich.
In order to further their understanding, German scientists have developed infection models to study the effects of plant extracts on the innate immune response and on the epigenetic regulation of gene expression (biochemical processes that activate and deactivate genes). In bladder cells, for example, they are studying the effect of traditional plants with urological activity, according to the German pharmacopoeia.
In collaboration with researchers at the Federal University of Minas Gerais (UFMG) in Brazil, it was found that some aqueous plant extracts (from species such as Solidago gigantea and Equiseti herba) significantly reduced the adhesion and survival of Escherichia coli in human bladder epithelial cells.
“We observed a drastic reduction in the adhesion and proliferation of this bacterium in bladder cells,” said Ulrich.
Fruit fibers
In Brazil, a group associated with the Food Research Center (FoRC) – one of FAPESP’s Research, Innovation and Dissemination Centers (RIDCs) – has focused on the technological prospection and evaluation of the biological effects on humans of non-digestible water-soluble polysaccharides (bioactive polysaccharides), such as pectins.
Found in papaya, passion fruit, and citrus fruits, pectins make up a large portion of the fiber in these fruits and have been linked to a reduction in chronic non-communicable diseases.
However, some of the challenges in extracting these compounds from fruits such as papaya are that they ripen very quickly, resulting in softening of the pulp and chemical modification of the structures of its pectins, which are linked to biological effects such as modulation of the gut microbiota.
“During fruit ripening, enzymes are expressed that modify the structure of the pectins, reducing their beneficial biological effects. Passion fruit and citrus pectins, on the other hand, must be chemically modified in order to present beneficial activities in the intestine,” João Paulo Fabi, professor at the School of Pharmaceutical Sciences of the University of São Paulo (FCF-USP) and coordinator of the project, told Agência FAPESP.
To do this, the Brazilian researchers developed techniques to extract pectin from the albedo of oranges and passion fruit – the white part between the peel and the pulp that is normally discarded when the fruit is processed to make juice – and to modify it in the laboratory to reduce its molecular complexity in order to increase its biological activity.
The development resulted in a patent for the process of extracting pectin from fleshy fruits such as papaya and chayote. A second patent covering the modification of pectin from passion fruit by-products is in the process of being filed.
“We already have a prototype for extracting and modifying these pectins on a laboratory scale. The idea is to obtain a product, such as a flour rich in modified pectin, that could be consumed as a supplement or food ingredient,” said Fabi.
In partnership with other groups, the researchers conducted animal studies to demonstrate the correlation between modified pectins and increased biological activity.
“These preclinical studies can serve as a basis for the development of clinical trials [with modified pectins] as adjuvants to chemotherapy treatment of colon cancer or even as beneficial modulators of the intestinal microbiota,” the researcher said.
The birth of modern Man
https://chuckincardinal.blogspot.com/
No comments:
Post a Comment
Stick to the subject, NO religion, or Party politics