In-Person Class Cancellations Halt Undergraduate Research on Campus – Cornell University The Cornell Daily Sun

Undergraduate students in the biological sciences honors program were informed on Wednesday afternoon that they will officially not be allowed to work in laboratories starting March 28, the deadline the University set after which all classes must be held online.

As a part of the honors program, students conduct novel, independent research and then write a formal honors thesis in a specific field of study. As a result of the disruption, participants should plan to collect as much data as possible before spring break, according to an email sent by Laura Schoenle, coordinator of undergraduate research and honors.

Even though aspects of the course will be cut short, students enrolled in Biology 4990: Independent Research in Biology, will receive full credit.

If you are enrolled in BIOG 4990, you will be able to receive full credit for the course, as we will have passed the 60% time point in the semester when we reach spring break, Schoenle wrote in an email to biological sciences honors students.

The decision was made in line with the Department of Educations guidelines for assigning credit in case of a disruption in instruction.

Although students living in off-campus housing may be inclined to continue working on their research projects, Cornell has discouraged working in research labs after March 27.

I was informed yesterday that Cornell does not want undergrads to continue working in research labs after March 27 even if you are living in off-campus housing and you plan to stay here in Ithaca, said Scott D. Emr, director of the Weill Institute for Cell and Molecular Biology, in an email to Weill Institute undergraduate students.

After March 27, honors students are encouraged to work with their laboratory research mentors to continue any data analysis and finish their theses remotely. The timeline for the program will remain the same, with students expected to submit their final papers to their group leader and committee for review by mid-April.

However, honors poster sessions to be held in May have been cancelled and the presentation requirement for honors will also be waived, according to Scheonle.

I realize these are challenging and stressful times. Please know that the entire university community, including the Bio Sci Honors Committee, has your best interests at heart, and respects the great efforts honors students put towards their research, Scheonle wrote.

The change in honors thesis policies sparked a variety of responses from students.

Natalie Brown 20, a Biology and Society major, works in Prof. Minglin Mas lab, biological and environmental engineering, pursuing an honors thesis project that investigates therapeutic approaches for diabetes.

I definitely understand that the decisions to cancel classes and close campus were made with consideration, but research isnt something you can just immediately pull out of, Brown said, who, like many students, acknowledged the necessity of the move while struggling to grapple with the effects of it.

Pooja Reddy 20 is a molecular and cell biology major that conducts research in Prof. Ankur Singhs lab, mechanical and aerospace engineering. For her honors thesis project, Reddy is studying how underlying health conditions, like metabolic syndrome, affect the effectiveness of vaccines.

In response to class cancellations, Reddy expressed concerns over finishing her experiments in time.

I planned on completing my experiments over the next 4 weeks to have them ready for my final thesis draft, but now I need to scramble to fit them all in two weeks, Reddy said. Having to do this while also saying goodbye to all my friends is super overwhelming and upsetting.

Claire Malkin 20, a computational biology major, works in Prof. Toshi Kawates lab, molecular medicine, studying the structure of a protein membrane receptor linked to chronic pain.

I was lucky to have just finished a lot of my data analysis so Im hoping that I can do work remotely, she said. [But] it is upsetting that we dont get to present our work, and its definitely harder to get feedback and continue work in the lab.

Even though Brown expressed frustration that many of us were planning to finish getting all of the data wed like to have during or after Spring Break, she appreciated steps being taken to accommodate undergraduates in the face of unforeseen circumstances.

I respect that measures are being taken to address the severity of this pandemic, and Im happy that we are still able to submit our theses for consideration at all, Brown said.

Whether these announced changes pertaining to biological sciences honors students will affect all undergraduate students doing research remains unclear.

For now, there is no specific guidance for students living off-campus, wrote Bill Loftus, director of administration for the Weill Institute for Cell and Molecular Biology, in an email sent to students and employees at the Weill Institute on Wednesday night. Presently, we do not know if undergrads can continue working in Institute labs after April 6. We are waiting for further clarification from the University.

Prof. Julia Thom-Levy, vice provost for academic innovation, did not respond for comment by the time of publication.

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In-Person Class Cancellations Halt Undergraduate Research on Campus - Cornell University The Cornell Daily Sun

Researchers solve the riddle of superbug toxin damage to gut – The Medical News

Reviewed by Emily Henderson, B.Sc.Mar 16 2020

A powerful Monash Biomedicine Discovery Institute (BDI) collaboration has revealed that a bacterial superbug can prevent stem cells in the gut from carrying out their vital role of regenerating the inner lining of the intestine. This causes potentially severe disease, particularly in the elderly.

The research found that Clostridioides difficile infection, the most common cause of hospital-acquired diarrhea, damages colonic stem cells via a toxin called TcdB, impairing tissue repair in the gut and recovery from disease. This understanding may now lead to new treatments or prevention methods.

C. difficile is responsible for more than half of all hospital infections related to the intestine and more than 90 per cent of mortalities resulting from these infections.

It grows after antibiotic treatment is administered to a patient, where it can upset the host-microbial balance in the gut allowing the bacterium to colonize.

The superbug can be transmitted from animals to humans and vice-versa and is now being uncovered in patients who have not had a recent hospital visit or taken a recent course of antibiotics. Instances have also been seen in a younger demographic than previously recorded.

The findings could have wider implications for those going through treatments for cancer such as chemotherapy and radiation therapy that also damage the gut.

The study, published in the journal Proceedings of the National Academy of Sciences of the United States of America (PNAS) today, was led by senior authors Professor Dena Lyras, an expert in infectious diseases, and Professor Helen Abud, an expert in stem cell biology, in conjunction with US collaborator Professor Borden Lacy from Vanderbilt University Medical Center in Nashville, Tennessee, who specializes in the structure of toxins. Joint first authors were Dr Steven Mileto (Lyras lab) and Dr Thierry Jard (Abud lab).

Our study provides the first direct evidence that a microbial infection alters the functional capacity of gut stem cells.

It adds a layer of understanding about how the gut repairs after infection and why this superbug can cause the severe damage that it does. The reason it's important to have that understanding is that we're rapidly running out of antibiotics - we need to find other ways to prevent and treat these infections."

Professor Helen Abud, expert in stem cell biology

"It shows that the toxins C. difficile makes are very important - TcdB targets the stem cells and damages them directly," Professor Lyras said.

"As a consequence, the gut can't be repaired. So where it normally takes five days to regenerate the gut lining, it can take more than two weeks. This can leave patients (particularly people aged over 65 years and who are already debilitated) with pain, life-threatening diarrhea and other serious conditions.

"By understanding this new mechanism of damage and repair, maybe we can find ways to prevent the damage happening or develop new treatments," Dr. Jard said.

The findings might also apply to other infections that behave in similar ways.

"There are a lot of different conditions that can make the gut more vulnerable - maybe there's a common way we can target them too instead of thinking in isolation about an infectious disease problem," said Dr. Mileto.

The work was funded by a joint National Health and Medical Research Council project grant gained by the two senior Monash BDI investigators. Professor Lyras was also supported by the Australian Research Council.

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Newly Discovered Memory in Our Bones: Keeping a Record of Previous Infections to Boost Immunity – SciTechDaily

Immune cells by fluorescence microscopy: Blood stem cells remember a previous attack and produce more immune cells like these macrophages to fight a new infection. Credit: Sieweke lab/CIML

These findings should have a significant impact on future vaccination strategies and pave the way for new treatments of an underperforming or over-reacting immune system. The results of this research are published in Cell Stem Cell on March 12, 2020.

Stem cells in our bodies act as reservoirs of cells that divide to produce new stem cells, as well as a myriad of different types of specialized cells, required to secure tissue renewal and function. Commonly called blood stem cells, the hematopoietic stem cells (HSC) are nestled in the bone marrow, the soft tissue that is in the center of large bones such as the hips or thighs. Their role is to renew the repertoire of blood cells, including cells of the immune system which are crucial to fight infections and other diseases.

Until a decade ago, the dogma was that HSCs were unspecialized cells, blind to external signals such as infections. Only their specialized daughter cells would sense these signals and activate an immune response. But work from Prof. Michael Siewekes laboratory and others over the past years has proven this dogma wrong and shown that HSCs can actually sense external factors to specifically produce subtypes of immune cells on demand to fight an infection. Beyond their role in an emergency immune response, the question remained as to the function of HSCs in responding to repeated infectious episodes. The immune system is known to have a memory that allows it to better respond to returning infectious agents. The present study now establishes a central role for blood stem cells in this memory.

We discovered that HSCs could drive a more rapid and efficient immune response if they had previously been exposed to LPS, a bacterial molecule that mimics infection, said Dr. Sandrine Sarrazin, Inserm researcher and senior-author of the publication. Prof. Michael Sieweke, Humboldt Professor at TU Dresden, CNRS Research Director and last author of the publication, explained how they found the memory was stored within the cells: The first exposure to LPS causes marks to be deposited on the DNA of the stem cells, right around genes that are important for an immune response. Much like bookmarks, the marks on the DNA ensure that these genes are easily found, accessible and activated for a rapid response if a second infection by a similar agent was to come.

The authors further explored how the memory was inscribed on the DNA, and found C/EBP? to be the major actor, describing a new function for this factor, which is also important for emergency immune responses. Together, these findings should lead to improvements in tuning the immune system or better vaccination strategies.

The ability of the immune system to keep track of previous infections and respond more efficiently the second time they are encountered is the founding principle of vaccines. Now that we understand how blood stem cells bookmark immune response circuits, we should be able to optimize immunization strategies to broaden the protection to infectious agents. It could also more generally lead to new ways to boost the immune response when it underperforms or turn it off when it overreacts, concluded Prof. Michael Sieweke.

The research group of Prof. Michael Sieweke works at the interface of immunology and stem cell research. The scientists focus on the study of hematopoietic stem cells and macrophages, long-lived mature cells of the immune system that fulfil an important role in tissue regeneration. In 2018, Prof. Michael Sieweke received the most valuable research award in Germany: the Alexander von Humboldt Professorship, which brings top international researchers to German universities. In addition to his position as Research Director at the Centre for Immunology at the University of Marseille Luminy, he now acts as Deputy Director at the Center for Regenerative Therapies at TU Dresden (CRTD). CRTD is academic home for scientists from more than 30 nations. Their mission is to discover the principles of cell and tissue regeneration and leveraging this for recognition, treatment and reversal of diseases. The CRTD links the bench to the clinic, scientists to clinicians to pool expertise in stem cells, developmental biology, gene-editing and regeneration towards innovative therapies for neurodegenerative diseases such as Alzheimers and Parkinsons disease, hematological diseases such as leukaemia, metabolic diseases such as diabetes, retina and bone diseases.

Reference: C/EBP-Dependent Epigenetic Memory Induces Trained Immunity in Hematopoietic Stem Cells by Brengre de Laval, Julien Maurizio, Prashanth K. Kandalla, Gabriel Brisou, Louise Simonnet, Caroline Huber, Gregory Gimenez, Orit Matcovitch-Natan, Susanne Reinhardt, Eyal David, Alexander Mildner, Achim Leutz, Bertrand Nadel, Christophe Bordi, Ido Amit, Sandrine Sarrazin and Michael H.Sieweke, 12 March 2020, Cell Stem Cell.DOI: 10.1016/j.stem.2020.01.017

This study was funded by TU Dresden / CRTD through the German Excellence Initiative, the German Research Foundation as well as through an ERC Advanced Grant from the European Research Council and the Alexander von Humboldt Foundation. The study was further supported by funding from the Institut National de la Sante et de la Recherche Medicale, the Centre National de la Recherche Scientifique, Aix-Marseille University, the Agence Nationale de la Recherche, the Foundation ARC pour la Recherche sur le Cancer, an INSERM-Helmholtz cooperation programme and the Einstein Foundation.

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Single Cell Analysis Market Size Worth $8.02 Billion By 2027 | CAGR: 16.9%: Grand View Research, Inc. – Yahoo Finance

SAN FRANCISCO, March 16, 2020 /PRNewswire/ -- The global single cell analysis marketsize is expected to reach USD 8.02 billion by 2027, registering a CAGR of 16.9% during the forecast period, according to a new report by Grand View Research, Inc. Advancements in molecular techniques which resulted in higher accuracy, ability to perform multiple omics analyses in one cell, and automation, has lowered the barriers for implementation of single-cell analysis techniques across various end-use settings. As a result, companies are investing in introducing novel solutions to accelerate the identification and quantification of genetic information in individual cells for research programs, thereby contributing to revenue growth in this market.

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This technology has addressed several research challenges with respect to biological intricacies in stem cell biology, tumor biology, immunology, and other therapeutic areas. This leads to improved therapeutic decision-making with regards to precision medicine, thereby driving the adoption of these assays in personalized therapeutic development.

The growth in research publications depicts the increasing R&D investments. Since R&D activities are considered as the foundation of innovation, investments in R&D activities signify a healthy growth prospect for the single cell analysis market. Moreover, the establishment of new single cell genomics centers in the past years is anticipated to boost the uptake of instruments and consumables for single cell analysis, thus driving the growth.

Grand View Research has segmented the global single cell analysis market on the basis of product, application, end use, and region:

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Grand View Research, U.S.-based market research and consulting company, provides syndicated as well as customized research reports and consulting services. Registered in California and headquartered in San Francisco, the company comprises over 425 analysts and consultants, adding more than 1200 market research reports to its vast database each year. These reports offer in-depth analysis on 46 industries across 25 major countries worldwide. With the help of an interactive market intelligence platform, Grand View Research helps Fortune 500 companies and renowned academic institutes understand the global and regional business environment and gauge the opportunities that lie ahead.

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To Turbocharge Anti-Aging Treatment, Just Add… a Protein Found in Fruit Flies? – Singularity Hub

The hunt for the elixir of life is such a universal mythological trope that to talk about it in the context of science seems almost ridiculous. But breakthroughs in the last decade have made the impossible seem possible, and researchers are quickly converging on the consensus that aging may well be a disease that we can treat just as easily as any other.

Impressive results in animals that have had their lifespans boosted by up to 40 percenthave started making their way into humans. Some trials are more questionable than others, but most promisingly there seem to be multiple potential avenues, from cocktails of common drugs to gene therapies and stem cell treatments.

Stem cells are particularly promising, because they can be coaxed into becoming any kind of cell before being transplanted to treat damaged tissue. These therapies often fail to work well in older tissue, though, limiting their future use in older patients who could need them most. This appears to be because these tissues have significantly higher levels of inflammation that prevent stem cells from properly integrating.

Now Portuguese researcher Joana Neves has won the 2019 Sartorius & Science Prize for Regenerating Medicine & Cell Therapy for her discovery of a way to sidestep this roadblock and significantly increase the success of stem cell treatments.

Because of the central importance of tissue repair to all organisms, Neves assumed that many of the mechanisms behind it would be shared among all animals. So she started looking at proteins produced by immune cells in the well-known animal model of the fruit fly.

She discovered that a poorly-understood protein known as MANF (mesencephalic astrocyte-derived neurotrophic factor) plays a crucial role in reducing inflammation in fruit flies. More importantly, she found that mice and humans also produce it, and its prevalence reduces in all the species as they age, suggesting it plays a key role in limiting age-related inflammation.

That prompted her to see if introducing MANF would boost the effectiveness of stem cell treatments in older animals. She used the protein in combination with a procedure that uses stem cells to replace degenerating photoreceptors in the retina of older mice and found it greatly improved the restoration of vision.

Going further, her research team then investigated whether MANFs anti-inflammatory effects could have more general age-defying benefits. Previous research had already demonstrated that infusing old mice with blood from younger ones could reduce various signs of aging, and by carrying out similar experiments the team showed that MANF is one of the factors responsible for that outcome. They even showed that directly injecting mice with MANF could have similar effects.

Translating these ideas to treat other diseases and for use in humans will take some time, but the research chimes with work on an emerging class of drugs known as senolytics. These are drugs that kill senescent cells, which are zombie cells that become more prevalent as we age and spew out harmful chemicals that result in chronic inflammation.

Senolytics are generally seen as a broad-spectrum treatment that could help stave off multiple conditions at once, but they could also be used to create a more hospitable environment for stem cell treatments just like MANF.

There are still plenty of barriers to bringing any of these treatments to the clinic, from the difficulty of producing stem cells to the challenges of regulating treatments for aging (a condition we still dont formally class as a disease), or fighting back against the huge number of bogus treatments that threaten to undermine trust in the field. But given the huge potential for near-term impact, theres growing momentum.

Weve moved from being able to extend health and lifespan of simple organisms like yeast and worms and flies to being able to do this quite easily in animals, in mice and monkeys, David Sinclair, director of the Center for the Biology of Aging at Harvard Medical School, told the Harvard Gazette.

He added that instead of trying to treat one disease at a time, he believes we can develop medicines that will treat aging at its source, therefore having a much greater impact on health and lifespan than drugs that target single diseases.

The wheels are in motion for us to find out.

Image Credit: Monika Robak from Pixabay

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Researchers develop new kind of CRISPR screen technology to target RNA – The Medical News

Reviewed by Emily Henderson, B.Sc.Mar 16 2020

CRISPR-based genetic screens have helped scientists identify genes that are key players in sickle-cell anemia, cancer immunotherapy, lung cancer metastasis, and many other diseases. However, these genetic screens are limited in scope: They can only edit or target DNA. For many regions of the human genome, targeting DNA may not be effective, and other organisms, such as RNA viruses like coronavirus or flu, cannot be targeted at all with existing DNA-targeting CRISPR screens.

Now, in an important new resource for the scientific community published today in Nature Biotechnology, researchers in the lab of Neville Sanjana, PhD, at the New York Genome Center and New York University have developed a new kind of CRISPR screen technology to target RNA.

The researchers capitalized on a recently characterized CRISPR enzyme called Cas13 that targets RNA instead of DNA. Using Cas13, they engineered an optimized platform for massively-parallel genetic screens at the RNA level in human cells. This screening technology can be used to understand many aspects of RNA regulation and to identify the function of non-coding RNAs, which are RNA molecules that are produced but do not code for proteins.

By targeting thousands of different sites in human RNA transcripts, the researchers developed a machine learning-based predictive model to expedite identification of the most effective Cas13 guide RNAs. The new technology is available to researchers through an interactive website and open-source toolbox to predict guide RNA efficiencies for custom RNA targets and provides pre-designed guide RNAs for all human protein-coding genes.

We anticipate that RNA-targeting Cas13 enzymes will have a large impact on molecular biology and medical applications, yet little is known about guide RNA design for high targeting efficacy. We set about to change that through an in-depth and systematic study to develop key principles and predictive modeling for most effective guide design."

Dr. Neville Sanjana, senior author of the study

Dr. Sanjana is a Core Faculty Member at the New York Genome Center, an Assistant Professor of Biology at New York University, and an Assistant Professor of Neuroscience and Physiology at NYU School of Medicine.

Cas13 enzymes are Type VI CRISPR (clustered regularly interspaced short palindromic repeats) enzymes that have recently been identified as programmable RNA-guided, RNA-targeting proteins with nuclease activity that allows for target gene knockdown without altering the genome. This property makes Cas13 a potentially significant therapeutic for influencing gene expression without permanently altering genome sequence.

"This is the kind of technology innovation that we foster and develop at the New York Genome Center. This latest CRISPR technology from the Sanjana Lab has exciting implications to advance the fields of genomics and precision medicine," said Tom Maniatis, PhD, Evnin Family Scientific Director and Chief Executive Officer, New York Genome Center.

Postdoctoral scientist Hans-Hermann Wessels and PhD student Alejandro Mndez-Mancilla, who are co-first authors of the study, developed a suite of new Cas13-based tools and conducted a transcript tiling and permutation screen in mammalian cells. In total, the researchers gathered information for more than 24,000 RNA-targeting guides.

"We tiled guide RNAs across many different transcripts, including several human genes where we could easily measure transcript knock-down via antibody staining and flow cytometry," said Dr. Wessels. "Along the way, we uncovered some interesting biological insights that may expand the application of RNA-targeting Cas13 enzymes." Among the team's findings, for example, are insights about which regions of the guide RNA are more important for recognition of a target RNA. Using thousands of guide RNAs with 1, 2 or 3 single-letter mismatches to their target RNA, they identified a critical "seed" region that is exquisitely sensitive to mismatches between the CRISPR guide and the target. This discovery will aid scientists in designing guide RNAs to avoid off-target activity on unintended target RNAs. Since a typical human cell expresses approximately 100,000 RNAs, accurate targeting of Cas13 of only the intended target is vital for screening and therapeutic applications.

In addition to furthering our understanding of Cas13 off-targets, the "seed" region could be used for next-generation biosensors that can more precisely discriminate between closely related RNA species. In total, this study increases the number of data points from previous Cas13 studies in mammalian cells by more than two orders of magnitude.

"We are particularly excited to use the optimized Cas13 screening system to target noncoding RNAs," said fellow co-first-author Mndez-Mancilla. "This greatly expands the CRISPR toolbox for forward genetic and transcriptomic screens." In the study, the researchers noticed a marked difference in protein knockdown when targeting different protein-coding and non-coding elements of messenger RNAs, and found evidence that Cas13 competes with other RNA-binding proteins involved in transcript processing and splicing.

The team recently leveraged their guide RNA predictive model for a particularly critical analysis: The COVID-19 public health emergency is due to a coronavirus, which contains an RNA - not DNA - genome. Using the model derived from their massively-parallel screens, the researchers have identified optimal guide RNAs that could be used for future detection and therapeutic applications. Predictions for Cas13 guide RNAs for a strain of SARS-CoV-2 isolated in New York have been made available online at: http://bit.ly/coronavirus-guides

Read more about the study at: https://www.nature.com/articles/s41587-020-0456-9. The web tool for predictive scoring of Cas13 guide RNAs can be found at http://cas13design.nygenome.org. Other coauthors on the study include, Mateusz Legut, PhD, and Zharko Daniloski, PhD, and NYU Biology PhD student Xinyi Guo.

Source:

Journal reference:

Wessels, H., et al. (2020) Massively parallel Cas13 screens reveal principles for guide RNA design. Nature Biotechnology. doi.org/10.1038/s41587-020-0456-9.

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Researchers develop new kind of CRISPR screen technology to target RNA - The Medical News

Effects of Supplementation with Anti-Inflammatory Compound Extracted f | VMRR – Dove Medical Press

Motoo Kobayashi,1,2,* Yuki Okada,1,2,* Hiromichi Ueno,1 Takayuki Mizorogi,1 Kenji Ohara,1 Koh Kawasumi,1 Kohei Suruga,3 Kazunari Kadokura,3 Yasuyuki Ohnishi,2 Toshiro Arai1,2

1Laboratory of Veterinary Biochemistry, School of Veterinary Medicine, Nippon Veterinary and Life Science University, Tokyo 180-8601, Japan; 2One Health Co. Ltd, Tokyo 157-0066, Japan; 3Food Function R&D Division, International Operation Department, Kibun Foods Inc., Tokyo 206-0812, Japan

*These authors contributed equally to this work

Correspondence: Toshiro AraiLaboratory of Veterinary Biochemistry, School of Veterinary Medicine, Nippon Veterinary and Life Science University, 1-7-1 Kyonancho, Musashino, Tokyo 180-8601, JapanTel +81 422 31 4151Fax +81 422 31 7841Email tarai@nvlu.ac.jp

Background: Obesity has become a serious public health problem all over the world, and prevalence of obesity has increased in cats. Obesity is characterized by continuous low-grade inflammation based on oxidative stress by excessively produced reactive oxygen species (ROS). Supplementation with anti-oxidant and anti-inflammatory compounds is very effective to relieve the obesity condition. A plant extract mixture containing Rhus verniciflua and some other herbs, Rv-PEM01-99, shows anti-oxidant and anti-inflammatory effects in animals. The aim of this study was to evaluate the effects of supplementation with Rv-PEM01-99 as an anti-inflammatory compound in healthy and obese cats.Materials and Methods: Ten healthy mix breed cats and four obesity disease cats were used. The healthy cats were randomly divided into control and test groups. Anti-inflammatory compound, Rv-PEM01-99, in which quercetin derivative is the main component, was supplemented to the healthy test group and the obesity disease cats at the dose of 100 120 mg/kg/day (2.5 3.0 mg/kg/day as quercetin) for 4 weeks. Metabolites, hormones and enzymes were measured before and after the compound supplementation.Results: The anti-inflammatory compound supplementation decreased serum amyloid A (SAA) concentrations as inflammatory markers in both healthy and obesity disease cats. In obesity disease cats, plasma total cholesterol concentrations and AST and ALT activities decreased significantly after the compound supplementation.Conclusion: Quercetin derivative seems to have strong anti-inflammatory activities. In the healthy cats, anti-inflammatory compound supplementation decreased plasma NEFA and SAA concentrations. In the obesity disease cats, the compound supplementation may have alleviated obesity disease by relieving inflammation and improvement of lipid metabolism in livers.

Keywords: anti-inflammatory compound, cat, obesity, quercetin, SAA

This work is published and licensed by Dove Medical Press Limited. The full terms of this license are available at https://www.dovepress.com/terms.php and incorporate the Creative Commons Attribution - Non Commercial (unported, v3.0) License.By accessing the work you hereby accept the Terms. Non-commercial uses of the work are permitted without any further permission from Dove Medical Press Limited, provided the work is properly attributed. For permission for commercial use of this work, please see paragraphs 4.2 and 5 of our Terms.

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Quantifying the Relationship Between Abnormal Liver Function Tests and Liver Breakdown – News-Medical.net

A study published in the Journal of Clinical Medicine has reported on the functional relationship between serum creatine kinase (CK) and liver biochemistry to determine the accuracy of liver function tests in the assessment of rhabdomyolysis.

Image Credits: Manjurul Haque / Shutterstock.com

The research team behind the study found that there was a statistically significant positive linear relationship between creatine kinase and alanine aminotransferase (ALT) amongst a range of associations explored.

This provides evidence that the increase in alanine aminotransferase can be anticipated on the basis of peak CK.

Rhabdomyolysis is a condition of muscle breakdown experienced in response to injury. The breakdown of muscle results in the release of cellular contents into the blood. The effects of this are far-ranging, resulting in cardiac arrhythmia and acute kidney injury (AKI) as a result of modified ion levels in the body.

Alongside this effect is the release of enzymes including creatine kinase (CK), lactate dehydrogenase, and aldolase. A clinical indicator of the severity of rhabdomyolysis is serum CK concentration. Most studies diagnose the syndrome when CK levels are present at five times above the upper limit of normal (1000 U/L).

The relevance of aminotransferases such as aspartate aminotransferase (AST) and alanine aminotransferase (ALT) to the diagnosis rhabdomyolysis, however, is underappreciated. Both are transiently increased in rhabdomyolysis, but ALT is a more specific indicator of liver despite both being distributed in other tissues.

ALT is 1-10 times more prevalent in the liver relative to other tissues. Given that adults only possess 20-30 Kg of skeletal muscle mass, relatively small amounts of ALT in the muscle may be detected at scale in the blood in instances where large muscle groups are injured.

The association between abnormal liver tests and rhabdomyolysis is unclear. Implications of this association may be adverse; from the false attribution of elevated aminotransferases to liver injury and invasive liver biopsies. Conversely, a failure to appreciate this association may lead to a missed diagnosis of muscle, rather than liver disease.

In addition, clinical trials of drugs with hepatotoxicity have complicated outcomes when subjects experience elevated serum aminotransferases from exercise-induced muscle damage. This has motivated the need to examine the relationship between liver biochemistry and CK levels in patients with severe rhabdomyolysis.

The group selected 528 patients with pressure injuries, the major mechanism of rhabdomyolysis.

The group found that peak CK and log ALT could be positively correlated among other biomarkers tested. The clinical implications of the relationship between peak CK and ALT are important.

Peak CK can be used to anticipate the increase in ALT in patients suffering from rhabdomyolysis. In cases where ALT lies outside the upper 95% confidence interval of the predicted ALT expected for a given peak CK, liver injury is suspected.

In practice, this would translate as a patient with a peak CK of 100,000 U/L without AKI or chronic liver disease possessing less than a 5% probability of returning an ALT above 200 U/L.

Other variables that showed a negative correlation with log-ALT were also discovered; these included patient age, the severity of AKI and Chronic kidney disease (CKD) stage. Chronic liver disease. Contrastingly the effect of age, AKI and chronic liver disease on log ALT were minor.

Of the other suspected biomarkers of liver disease tested, there was no correlation found between the log-creatine kinase and the log-bilirubin, log-alkaline phosphatase, or log--glutamyl transferase.

This study represents the first to determine the relationship between the variables that are known or assumed to complicate the association between CK and ALT. However, the study was limited by the lack of data on AST. Moreover, in the absence of baseline liver function, it was not possible to determine whether an elevated ALT may be a pre-existing problem in some patients.

In some cases, abnormal ATL was transient and was normalized upon patient discharge. Information concerning the timings of discharge, histological data, and availability of biochemistry was also lacking, limiting data. Most notably, the predicted level of ALT may have been underestimated as previous studies suggest that peak ALT typically occurs 2448 h after peak CK.

Lim, AKH et al. (2020) A Cross-Sectional Study of the Relationship between Serum Creatine Kinase and Liver Biochemistry in Patients with Rhabdomyolysis. J. Clin. Med. Doi: 10.3390/jcm9010081

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Hassan: Kannadiga involved with vaccine research for coronavirus – Daijiworld.com

Daijiworld Media Network - Hassan (SP)

Hassan, Mar 17: A native of Hassan district has won a place in a team of scientists who are engaged with the task of finding out a vaccine to bring deadly coronavirus under control. He is Mahadesh Prasad from Arkalgud taluk in the district.

Prasad has been a part of the European Task Force for Coronavirus team. Mahadesh was earlier serving in Germany as a scientist. When Prime Minister Narendra Modi, gave a call to scientists from India working elsewhere to return to their motherland, Mahadesh Prasad had returned. Now he is in Belgium.

Mahadesh has been involved with research there. Countries in Europe have formed ten teams to find a vaccine for coronavirus. World Health Organization has formed ten teams to conduct research on this subject. Mahadesh Prasad has made Karnataka proud by securing a place in this team.

Prasad's family members currently live in Mysuru.

Prasad gets credit for being the first ever youngest person to complete PhD in biochemistry in the history of Mysore University. For his achievements at such a young age, he also has been identified as the first young scientist to have bagged five national and international awards for his achievements in the field of research.

Mahadesh bagged Visiting Virology Fellowship Award of Belgium in 2019, Science and Engineering Research Board's Young Scientist Award in 2016, Post Doctoral Fellowship Award of Sweden in 2012, NIH Post Doctoral Fellowship Award from USA in 2010 and DAAD Fellowship Award from Germany in 2009.

Mahadesh has so far presented 16 research papers at the international level on various subjects including biochemistry, virology, stem cell biology, tumour virology, cancer genetics and system vaccinology. The European Council has recognized him as a certified lab animal expert.

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Hassan: Kannadiga involved with vaccine research for coronavirus - Daijiworld.com

STEM lab to expand to another course in fall semester Funded by the University System of – News at UNG

When University of North Georgia (UNG) faculty members noticed students leaving science, technology, engineering, and mathematics (STEM) programs, they devised and implemented an innovative lab to retain them.

In a three-hour STEM lab during the spring semesters, freshmen and sophomores learn about biology, chemistry and physics from a trio of faculty members teaching as a team. Students collaborate on real-world issues, conduct research projects and compare their lab work to that done by professional scientists.

"They are learning the techniques that scientists are actually doing in the field," said Dr. Royce Dansby-Sparks, associate professor of chemistry at UNG and one of the faculty members who taught the STEM lab. He has ceased work with it since becoming director of the Honors Program on UNG's Dahlonega Campus. "Students also learn soft skills such as how to work on a team and oral communication skills that they don't learn in a traditional chemistry, biology or physics lab."

Funded by the University System of Georgia's (USG) Complete College Georgia initiative, the STEM lab has proven so effective for five years it is expanding to a full academic year, with STEM 1001 in the fall and STEM 1002 in the spring. Dr. John Leyba, interim dean of the College of Science and Mathematics, said the USG STEM IV initiative has awarded $150,000 to UNG for the project.

"The money will allow us to expand the STEM lab to the fall semester," he said. "It also will allow us to add a significant research component this spring."

Leyba explained STEM lab students must find a mentor in biology, chemistry, mathematics, or physics and develop a research proposal. Students will present their ideas to a panel of three faculty members near the spring semester's end. The panel will decide to fund some of the projects.

"We will fund probably half of the projects," Leyba said. "This will allow us to pay the student and the professor stipends, and allow us to pay for the supplies for the research for up to two semesters."

Dr. Jeremy Olson, lecturer of chemistry who replaced Dansby-Sparks in the STEM lab, said while the written proposal is required, performing the research is not.

"But they want to do it, and they would get paid to do research," he said, adding it will help students who plan to apply for graduate school. "Very few students have experience writing a research proposal, especially as a freshman."

Dansby-Sparks said research projects conducted in the STEM labs have proven beneficial in more ways than one.

He pointed to the success of UNG alumna Caroline Brown as an example of the impact the STEM lab and undergraduate research can have for students who are trying to find their place in the STEM field. Brown participated in the inaugural STEM lab as a freshman, which is when Dansby-Sparks noticed her aptitude for research.

"Caroline Brown came in as a biology major and she jumped ship to biochemistry," he said. "Now she is getting her Ph.D. in cell biology at Yale University."

The STEM lab also is producing its desired results of retention. Dansby-Sparks said 58 percent of students who participated in STEM lab have remained in STEM fields after four semesters. For students in traditional labs, 42.9 percent remained in STEM fields.

"The students are also self-reflective and indicate they find the context meaningful," Dansby-Sparks said. "They are also ahead of their peers in the junior and senior level."

Leyba explained the STEM lab is also in line with the College of Science and Mathematics expansion plans. Once the two STEM lab courses are established as a sequence for spring and fall semesters, it will be implemented on the Gainesville Campus in 2021 followed by a learning community there.

"All of this has motivated us to apply for funding from the Howard Hughes Medical Institution," Leyba said.

The Howard Hughes Medical Institute is a science philanthropy whose mission is to advance basic biomedical research and science education for the benefit of humanity. It is one of the largest private funding organizations for biological and medical research in the United States.

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STEM lab to expand to another course in fall semester Funded by the University System of - News at UNG