Two different gene therapies have been used to mitigate a mechanism underlying development of sickle cell disease (SCD) and transfusion-dependent -thalassemia (TDT), and both have demonstrated clinical success in separate, concurrently published trials.

The hemoglobinopathies manifest after fetal hemoglobin synthesis is replaced by adult hemoglobin in individuals who have inherited a mutation in the hemoglobin subunit gene (HBB).Identifying factors in the conversion from fetal to adult hemoglobin synthesis, however, has provided potential targets for therapeutic intervention.

Gene therapy that can safely arrest or reduce the conversion offers the potential for a one-time treatment to obviate the need for lifetime transfusions and iron chelation for patients with TDT, and the pain management, transfusions and hydroxyurea administration for those with SCD.

Two groups of investigators have now reported in The New England Journal of Medicine that, using different gene therapy techniques that target the transcription factor, BCL11a, involved in the globin switching, they have improved clinical outcomes in patients with TDT and with SCD.

In an editorial in the issue featuring the 2 studies, Mark Walters, MD, Blood and Marrow Transplant Program, University of California, San Francisco-Benioff Children's Hospital, welcomed the breakthroughs.

"These trials herald a new generation of broadly applicable curative treatments for hemoglobinopathies," Walters wrote.

In one clinical trial with 2 patients, one with TDT and the other with SCD, Haydar Frangoul, MD, MS, Medical Director, Pediatric Hematology/Oncology, Sarah Cannon Center for Blood Cancer at the Children's Hospital at Tristar Centennial, and colleagues administered CRISPR-Cas9 gene edited hematopoietic stem and progenitor cells (HSPCs) with reduced BCL11A expression in the erythroid lineage.

The product, CTX001, had been shown in preclinical study to restore -globulin synthesis and reactivate production of fetal hemoglobin. Both patients underwent busulfan-induced myeloablation prior to receiving the treatment.

The investigators suggested that the CRISPR-Cas9-based gene-edited product could change the paradigm for patients with these conditions, if it was found to successfully and durably graft, produce no "off-target" editing products, and, importantly, improve clinical course.

"Recently approved therapies, including luspatercept and crizanlizumab, have reduced transfusion requirements in patients with TDT and the incidence of vaso-occlusive episodes in those with SCD, respectively, but neither treatment addressed the underlying cause of the disease nor fully ameliorates disease manifestations," Frangoul and colleagues wrote.

The investigators reported that both patients had "early, substantial, and sustained increases" in pancellularly distributed fetal hemoglobin levels during the 12-month study period. Further, the patients no longer required transfusions, and the patient with SCD no longer experienced vaso-occlusive episodes after the treatment.

In commentary accompanying the report, Harry Malech, MD, Genetic Immunotherapy Section, Laboratory of Clinical Immunology and Microbiology, National Institute of Allergy and Infectious Disease (NIAID), National Institutes of Health (NIH), Bethesda, MD, described the investigators' application of the gene-editing technology as a "remarkable level of functional correction of the disease phenotype."

"With tangible results for their patients, Frangoul et al have provided a proof of principle of the emerging clinical potential for gene-editing treatments to ameliorate the burden of human disease," Malech pronounced.

In the other published trial, with 6 patients with SCD, Erica Esrick MD, Dana-Farber/Boston Children's Cancer and Blood Disorders Center, Harvard Medical School, and colleagues described results with infusion of gene-modified cells derived from lentivirus insertion of a gene that knocks down BCL11a by encoding an erythroid-specific, inhibitory short-hairpin RNA (shRNA).

The severity of SCD that qualified patients for enrollment included history of stroke (n = 3), frequent vaso-occlusive events (n = 2) and frequent episodes of priapism (1).Patients were followed for 2 years, and offered enrollment in a 13-year long-term follow-up study.The infusion of the experimental drug BCH-BB694, from the short hairpin RNA embedded within an endogeonous micro RNA scaffold (termed a shmiR vector), was initiated after myeloablation with busulfan.

Esrick and colleagues reported that, at median follow-up of 18 months (range, 7-29), all patients had engraftment and a robust and stable HbF induction broadly distributed in red cells.Clinical manifestations of SCD were reduced or absent during the follow-up period; with no patient having a vaso-occlusive crisis, acute chest syndrome, or stoke subsequent to the gene therapy infusion.Adverse events were consistent with effects of the preparative chemotherapy.

"The field of autologous gene therapies for hemoglobinopathies is advancing rapidly," Esrick and colleagues reported, "including lentiviral trials of gene addition in which the nonsickling hemoglobin is formed from an exogenous -globin or modified -globin gene."

Walters agreed that gene therapy is rapidly progressing, but expressed concern about the large gap that looms between laboratory bench and clinical bedside, particularly for this affected population.

"Access to and delivery of these highly technical therapies in patients with sickle cell disease will be challenging and probably limited to resource-rich nations, at least in the short term," Walters commented.

The studies, CRISPR-Cas9 Gene Editing for Sickle Cell Disease and -Thalassemia, as well as, Post-Transcriptional Genetic Silencing of BCL11A to Treat Sickle Cell Disease, were published online in The New England Journal of Medicine.

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Two Gene Therapies Fix Fault in Sickle Cell Disease and -thalassemia - MD Magazine

WILLOWBROOK, Ill., Jan. 26, 2021 /PRNewswire/ --Based in Willowbrook, Illinois, Russell Health, a national marketer and distributor of specialty medical products and services, has recently been issued company trademark registrations from the United States Patent and Trademark Office.

Russell Health, Inc., a leading regenerative medicine company, announced today the United States Patent and Trademark Officehas issued registrations for the company's trademarks - Stem Cell Recruitment Therapy (Reg. No. 6,109,514) and Stem Cell Recruitment Facial (Reg. No. 6,218,705), signifying that the company has met the stringent United States standards for exclusively applying its trademarks to the company's products.

Media Approved Quote:"Being a leader in regenerative medicine, we have made it a priority to invest in our Intellectual Property and trademarks across our company. We are excited at the Patent Office's decision to award us with two highly valuable registered trademarks. We are planning to expand our Stem Cell Recruitment Therapy and Stem Cell Recruitment Facial brands nationwide." (Ryan Salvino, CEO)

About Russell Health: Russell Health is a national marketer and distributor of specialty medical products and services. Together with our partners and suppliers, we work to provide innovative life-changing and sustaining products and therapies to patients and healthcare providers around the world. Russell Health and its partners have distributed regenerative therapy products nationwide and achieved profound clinical outcomes in multiple therapeutic areas including cosmetics, wound care, pain management, podiatry, orthopedics, ocular and gynecology. Our knowledge of national markets combined with our strong industry relationships, our location and our relevant industry experience make us highly effective at building sales channels that deliver great results. We pride ourselves in having a high level of integrity and being a trusted partner and advisor to our practitioners, manufacturers and patients. These trademarks exclusively distinguish our fine products and services from those of other products in the industry.Customers can always count on Russell Health for the best quality specialty medical and regenerative products solutions in a variety of specialty areas.

Disclaimer

Stem Cell Recruitment (SCR), Stem Cell Recruitment Therapy (SCRT), Stem Cell Recruitment Facial ,DermaFlo, OrthoFactor and Vivaderm are trademarks of Russell Health, Inc. The treatments described on thismarketing are not considered to be standard of care for any condition or disease. SCR, SCRT, SCR Facial andVivaderm attempt to utilize acellular, minimally manipulated tissue allografts and are comprised of tissue allograftcomponents intended for homologous use to supplement tissue. These statements have not been evaluated by the FDA.This product is not intended to diagnose, treat, cure or prevent any disease. Results may vary.

Visit Russell Health online to learn more about Stem Cell Recruitment Therapy. For media inquiries or to contact the Russell Health team directly. Please visit http://www.russellhealth.comor email [emailprotected].

Contact:

Veronica BennettPhone: 312-919-1896Email: [emailprotected]

Mailing Address: 621 Plainfield Rd., Willowbrook, IL 60527

Online: http://www.russellhealth.com

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SOUTH SAN FRANCISCO, Calif., Jan. 27, 2021 (GLOBE NEWSWIRE) -- Global Blood Therapeutics , Inc. (GBT) (NASDAQ: GBT) today announced that the European Medicines Agency (EMA) has completed the validation of GBTs Marketing Authorization Application (MAA) for Oxbryta (voxelotor) tablets and started its standard review process. GBT is seeking full marketing approval from the EMA for Oxbryta to treat hemolytic anemia in patients with sickle cell disease (SCD) who are 12 years of age and older.

A first-in-class oral, once-daily therapy, Oxbryta directly inhibits hemoglobin polymerization, the root cause of the sickling and destruction of red blood cells in SCD. The sickling process causes hemolytic anemia (low hemoglobin due to red blood cell destruction) and blockages in capillaries and small blood vessels, which impede the flow of blood and oxygen throughout the body. The diminished oxygen delivery to tissues and organs can lead to life-threatening complications, including stroke and irreversible organ damage.1-4

Sickle cell disease has a devastating impact on the lives of patients and their families, including serious and life-threatening complications that can lead to organ damage and early death, said Ted W. Love, M.D., president and chief executive officer of GBT. Despite this overwhelming need, there are currently no approved therapies in Europe that have the potential to modify the course of the disease. We look forward to working with the EMA to meet our goal of bringing the first treatment for hemolytic anemia in sickle cell disease to European patients as soon as possible.

The MAA is based on data from the Phase 3 HOPE (Hemoglobin Oxygen Affinity Modulation to Inhibit HbS PolymErization) Study and the Phase 2 HOPE-KIDS 1 Study, both of which enrolled patients at clinical sites in Europe. The HOPE Study achieved its primary endpoint of an improvement in hemoglobin (Hb) levels of greater than 1 g/dL at 24 weeks with significant improvements in markers of hemolysis in indirect bilirubin and reticulocyte percentage.5 The most common side effects reported in the HOPE Study at 24 weeks occurring in 10% of patients treated with Oxbryta with a difference of >3% compared to placebo were headache (26% vs. 22%), diarrhea (20% vs. 10%), abdominal pain (19% vs. 13%), nausea (17% vs. 10%), fatigue (14% vs. 10%), rash (14% vs. 10%) and pyrexia (12% vs. 7%).6

The analysis of the complete data from the HOPE Study further demonstrated that Oxbryta, at a daily dose of 1500 mg, resulted in durable improvements in Hb levels and markers of hemolysis over 72 weeks of treatment in SCD patients 12 years of age and older. Treatment with Oxbryta was well tolerated, with no new safety or tolerability issues identified. The 72-week results from the HOPE Study were presented at the 62nd American Society of Hematology (ASH) Annual Meeting and Exposition in December 2020.7

The EMA previously granted Oxbryta Priority Medicines (PRIME) designation, and the European Commission (EC) designated Oxbryta as an orphan medicinal product for the treatment of patients with SCD.

There are an estimated 52,000 people living with SCD in Europe. To help support patients living in Europe prior to potential marketing authorization, GBT has initiated an Early Access Program in Europe and other regions outside the United States, which enables physicians to utilize early access regulatory and legal pathways to request Oxbryta for the treatment of hemolytic anemia in eligible patients with SCD who do not have access to the medicine as part of a clinical trial.

Oxbryta is approved in the United States for the treatment of SCD in adults and children 12 years of age and older.

About Sickle Cell DiseaseSickle cell disease (SCD) affects an estimated 100,000 people in the United States,8 an estimated 52,000 people in Europe,9 and millions of people throughout the world, particularly among those whose ancestors are from sub-Saharan Africa.8 It also affects people of Hispanic, South Asian, Southern European and Middle Eastern ancestry.8 SCD is a lifelong inherited rare blood disorder that impacts hemoglobin, a protein carried by red blood cells that delivers oxygen to tissues and organs throughout the body.10 Due to a genetic mutation, individuals with SCD form abnormal hemoglobin known as sickle hemoglobin. Through a process called hemoglobin polymerization, red blood cells become sickled deoxygenated, crescent-shaped and rigid.1-2,10

About Oxbryta (voxelotor) TabletsOxbryta (voxelotor) is an oral, once-daily therapy for patients with sickle cell disease (SCD). Oxbryta works by increasing hemoglobins affinity for oxygen. Since oxygenated sickle hemoglobin does not polymerize, GBT believes Oxbryta blocks polymerization and the resultant sickling and destruction of red blood cells, which are primary pathologies faced by every single person living with SCD. Through addressing hemolytic anemia and improving oxygen delivery throughout the body, GBT believes that Oxbryta has the potential to modify the course of SCD. On Nov. 25, 2019, Oxbryta received U.S. Food and Drug Administration (FDA) accelerated approval for the treatment of SCD in adults and children 12 years of age and older.6

As a condition of accelerated approval in the United States, GBT will continue to study Oxbryta in the HOPE-KIDS 2 Study, a post-approval confirmatory study using transcranial Doppler (TCD) flow velocity to assess the ability of the therapy to decrease stroke risk in children 2 to 15 years of age.

In recognition of the critical need for new SCD treatments, the FDA granted Oxbryta Breakthrough Therapy, Fast Track, Orphan Drug and Rare Pediatric Disease designations for the treatment of patients with SCD. Additionally, Oxbryta has been granted Priority Medicines (PRIME) designation from the European Medicines Agency (EMA), and the European Commission (EC) has designated Oxbryta as an orphan medicinal product for the treatment of patients with SCD.

GBT plans to seek regulatory approval for the potential use of a pediatric formulation of Oxbryta in the United States for the treatment of SCD in children as young as 4 years old.

Important Safety InformationOxbryta should not be taken if the patient has had an allergic reaction to voxelotor or any of the ingredients in Oxbryta. See the end of the patient leaflet for a list of the ingredients in Oxbryta.

Oxbryta can cause serious side effects, including serious allergic reactions. Patients should tell their health care provider or get emergency medical help right away if they get rash, hives, shortness of breath or swelling of the face.

Patients receiving exchange transfusions should talk to their health care provider about possible difficulties with the interpretation of certain blood tests when taking Oxbryta.

The most common side effects of Oxbryta include headache, diarrhea, stomach (abdominal) pain, nausea, tiredness, rash and fever. These are not all the possible side effects of Oxbryta.

Before taking Oxbryta, patients should tell their health care provider about all medical conditions, including if they have liver problems; if they are pregnant or plan to become pregnant as it is not known if Oxbryta can harm an unborn baby; or if they are breastfeeding or plan to breastfeed as it is not known if Oxbryta can pass into breastmilk or if it can harm a baby. Patients should not breastfeed during treatment with Oxbryta and for at least two weeks after the last dose.

Patients should tell their health care provider about all the medicines they take, including prescription and over-the-counter medicines, vitamins and herbal supplements. Some medicines may affect how Oxbryta works. Oxbryta may also affect how other medicines work.

Patients are advised to call their doctor for medical advice about side effects. Side effects can be reported to the FDA at 1-800-FDA-1088. Side effects can also be reported to Global Blood Therapeutics at 1-833-428-4968 (1-833-GBT-4YOU).

Full Prescribing Information for Oxbryta is available at Oxbryta.com.

About Global Blood TherapeuticsGlobal Blood Therapeutics (GBT) is a biopharmaceutical company dedicated to the discovery, development and delivery of life-changing treatments that provide hope to underserved patient communities. Founded in 2011, GBT is delivering on its goal to transform the treatment and care of sickle cell disease (SCD), a lifelong, devastating inherited blood disorder. The company has introduced Oxbryta (voxelotor), the first FDA-approved treatment that directly inhibits sickle hemoglobin polymerization, the root cause of red blood cell sickling in SCD. GBT is also advancing its pipeline program in SCD with inclacumab, a P-selectin inhibitor in development to address pain crises associated with the disease, and GBT021601, the companys next generation hemoglobin S polymerization inhibitor. In addition, GBTs drug discovery teams are working on new targets to develop the next wave of treatments for SCD. To learn more, please visit http://www.gbt.com and follow the company on Twitter @GBT_news.

Forward-Looking Statements Certain statements in this press release are forward-looking within the meaning of the Private Securities Litigation Reform Act of 1995, including statements containing the words will, anticipates, plans, believes, forecast, estimates, expects and intends, or similar expressions. These forward-looking statements are based on GBTs current expectations, and actual results could differ materially. Statements in this press release may include statements that are not historical facts and are considered forward-looking within the meaning of Section 27A of the Securities Act of 1933, as amended, and Section 21E of the Securities Exchange Act of 1934, as amended. GBT intends these forward-looking statements, including statements regarding GBTs priorities, dedication, focus, goals and vision; safety, efficacy and mechanism of action of Oxbryta and other product characteristics; significance of reducing hemolysis and raising hemoglobin; commercialization, delivery, availability, use, and commercial and medical potential of Oxbryta; ongoing and planned studies of Oxbryta and related protocols, activities and expectations; potential expansion of the approved use of Oxbryta for more patients in the U.S.; potential regulatory approval for Oxbryta to treat patients in Europe, including the EMAs review of the related MAA, working with the EMA and bringing the first treatment for hemolytic anemia in SCD to European patients; the early access program for Oxbryta, including the potential availability, use and impact; altering the treatment, course and care of SCD and mitigating related complications; potential and advancement of GBTs pipeline, including inclacumab and other product candidates; and working on new targets and discovering, developing and delivering treatments, to be covered by the safe harbor provisions for forward-looking statements contained in Section 27A of the Securities Act and Section 21E of the Securities Exchange Act, and GBT makes this statement for purposes of complying with those safe harbor provisions. These forward-looking statements reflect GBTs current views about its plans, intentions, expectations, strategies and prospects, which are based on the information currently available to the company and on assumptions the company has made. GBT can give no assurance that the plans, intentions, expectations or strategies will be attained or achieved, and, furthermore, actual results may differ materially from those described in the forward-looking statements and will be affected by a variety of risks and factors that are beyond GBTs control including, without limitation, risks and uncertainties relating to the COVID-19 pandemic, including the extent and duration of the impact on GBTs business, including commercialization activities, regulatory efforts, research and development, corporate development activities and operating results, which will depend on future developments that are highly uncertain and cannot be accurately predicted, such as the ultimate duration of the pandemic, travel restrictions, quarantines, social distancing and business closure requirements in the U.S. and in other countries, and the effectiveness of actions taken globally to contain and treat the disease; the risks that GBT is continuing to establish its commercialization capabilities and may not be able to successfully commercialize Oxbryta; risks associated with GBTs dependence on third parties for development, manufacture, distribution and commercialization activities related to Oxbryta; government and third-party payor actions, including those relating to reimbursement and pricing; risks and uncertainties relating to competitive products and other changes that may limit demand for Oxbryta; the risks regulatory authorities may require additional studies or data to support continued commercialization of Oxbryta; the risks that drug-related adverse events may be observed during commercialization or clinical development; data and results may not meet regulatory requirements or otherwise be sufficient for further development, regulatory review or approval; compliance with obligations under the Pharmakon loan; and the timing and progress of GBTs and Syros research and development activities under their collaboration; along with those risks set forth in GBTs Annual Report on Form 10-K for the fiscal year ended December 31, 2019, and in GBTs most recent Quarterly Report on Form 10-Q filed with the U.S. Securities and Exchange Commission, as well as discussions of potential risks, uncertainties and other important factors in GBTs subsequent filings with the U.S. Securities and Exchange Commission. Except as required by law, GBT assumes no obligation to update publicly any forward-looking statements, whether as a result of new information, future events or otherwise.

References

Contact:Steven Immergut (media)650.410.3258simmergut@gbt.com

Courtney Roberts (investors)650.351.7881croberts@gbt.com

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European Medicines Agency Accepts GBT's Marketing Authorization Application (MAA) for Oxbryta (voxelotor) for the Treatment of Hemolytic Anemia in...

PROVIDENCE, R.I. [Brown University] Dr. MartinA.Weinstock, a professor of dermatology and epidemiology at Brown University, will lead a six-year clinical trial to evaluate the effectiveness of a topical medication as a way to prevent the most common type of cancer in the United States.

Backed by a $34 million award from the U.S. Department of Veterans Affairs Cooperative Studies Program, the study will investigate the potential of imiquimod, a topical medication with minimal side effects, as a preventive measure against basal cell carcinoma. Weinstock who is the chief of dermatology research for the V.A. Providence Healthcare System will lead the trial with co-chair Dr. Robert Dellavalle, chief of dermatology for the V.A. Eastern Colorado Health Care System and a University of Colorado School of Medicine professor.

Basal cell carcinoma usually occurs on the face and requires surgery to avoid serious complications. An effective preventive medication could help many patients avoid or at least postpone the risks of surgery, and decrease the need for medical visits and their resulting costs, Weinstock said.

These lesions are typically treated with what I call a cut and wait approach, he said, noting that skin damage and scarring are undesirable side effects. Unfortunately, we dont have anything better right now.

More than 1,600 participants, including U.S. military veterans at high risk for basal cell carcinoma, will be recruited from 17 V.A. medical centers for the trial. They will apply the cream to their faces daily for up to 12 weeks and be followed actively for three years to see if their skin cancer risk is reduced, with an additional year of passive follow-up. In addition to evaluating effectiveness of the treatment, researchers will collect genetic material from some participants to determine factors that may indicate greater risk reduction and better tolerance of imiquimod therapy. This will help target therapy to those who will benefit from it the most.

Weinstock said that developing ways to actively prevent basal and squamous cell carcinoma has been a goal since he joined the Brown faculty in 1988. He has been involved with two other national studies directed at skin cancer therapies one of these clinical trials found that topical application of a cream containing 5-fluorouracil 5% reduced the risk of squamous cell carcinoma by 75% for a year.

Theres good reason to believe that well see in this upcoming trial that imiquimod has similar preventative effects on BCC, Weinstock said. And if that turns out to be the case, he said, it would fundamentally transform our approach to the disease we need to proactively prevent this cancer that afflicts millions each year."

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Clinical trial to evaluate whether topical medication can prevent common skin cancer - Brown University

Mario Gutierrez consults Prof. Lola Eniola while using fluorescent microscopy to study the effect of red blood rigidification on the thermodynamics of blood flow. Graduate students and post-docs work at Prof. Lola Eniolas Cell Adhesion & Drug Delivery Lab in North Campus Research Complex. Image credit: Marcin Szczepanski/Multimedia Director and Senior Producer, University of Michigan, College of Engineering

White researchers are nearly twice as likely to be awarded a grant than Black scientists of similar academic achievement, studies of National Institutes of Health funding programs showand a group of 19 biomedical engineering leaders is calling on NIH and other funding agencies to address the stark disparity.

Lola Eniola-Adefeso

In 2019 alone, the gap amounted to $32 million.

The authors of the commentary paper, published this week in the journal Cell, are representatives of a network of women deans, chairs and distinguished faculty.

Black scientists in biomedicine are not getting funding, which means theyre not getting tenure, and theyre not getting promoted, said Omolola Eniola-Adefeso, the University Diversity and Social Transformation Professor of Chemical Engineering at the University of Michigan and senior author of the paper.

When they leave the profession, we lose these individuals in the classroomand research shows that women and minorities persist in science and engineering when they see people who look like them.

It also means that many research questions vital to the Black community and society at large are not being asked because the perspectives, creativity and knowledge of a diverse population of scientists are not being tapped, she says.

In addition, the public does not see the faces or hear the voices of Black scientific experts speaking on important issues, she says. This contributes to distrust of medicine and medical technology in the Black communityincluding the COVID-19 vaccines.

If science doesnt represent all these communities, if health care doesnt represent them, how can we expect to serve them equally? asked lead author Kelly Stevens, assistant professor of bioengineering and of laboratory medicine and pathology at the University of Washingtons School of Medicine and College of Engineering.

The authors recommend several steps that funding agencies can take to eliminate disparities, including:

The authors also suggested ways individual researchers and universities, colleges and institutes can address discriminatory trends in academic processes. And they charted out a role for the private sector, including foundations, professional societies and philanthropists, as well as to industry leaders whose companies depend on scientific innovation, to help offset racial disparities in research funding.

The authors heralded biotech company Genentech as a leader, as the firm recently created a research funding program for Black scientists. If funding agencies and academic institutions wont address the gap, the remaining $31.5 million is well within range for the biomedical industry.

Eniola-Adefeso is also a member of the U-M Biointerfaces Institute. Stevens is also an investigator at the UW Medicine Institute for Stem Cell and Regenerative Medicine.

Other engineering faculty researchers co-authoring the paper are: Kristyn Masters, University of Wisconsin; Princess Imoukhuede and Lori Setton, Washington University St. Louis; Karmella Haynes, Emory University; Elizabeth Cosgriff-Hernandez and Shelly Sakiyama-Elbert, University of Texas; Muyinatu Lediju Bell, Johns Hopkins University; Padmini Rangamani and Karen Christman, University of California San Diego; Stacey Finley, University of Southern California; Rebecca Willits and Abigail Koppes, Northeastern University; Naomi Chesler, University of California Irvine; Josephine Allen, University of Florida in Gainesville; Joyce Wong, Boston University; and Hana El-Samad and Tejal Desai, University of California San Francisco.

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How to end discrimination in health research funding - University of Michigan News

Human vasculature model created using Print to Perfusion process

Human vasculature model created using Print to Perfusion process (Image courtesy of United Therapeutics)

ROCK HILL, S.C., Jan. 27, 2021 (GLOBE NEWSWIRE) -- 3D Systems (NYSE:DDD) today announced its decision to significantly expand its development efforts focused on regenerative medicine and bioprinting solutions. This decision was driven by the tremendous progress made in collaboration with United Therapeutics Corporation (NASDAQ:UTHR) and its organ manufacturing and transplantation-focused subsidiary, Lung Biotechnology PBC, on the development of 3D printing systems for solid-organ scaffolds. Leveraging this work as well as accomplishments with additional partners, 3D Systems intends to invest, further develop, and commercialize solutions for the diverse application opportunities in regenerative medicine, including the development of non-solid organ applications requiring biologically sustainable vasculature.

In 2020, 3D Systems and United Therapeutics achieved significant progress in the development of a next-generation additive manufacturing platform solution for lung scaffolds that is capable of full size, vascularized, rapid, micron-level printing. 3D Systems capabilities as a technology innovator, spanning hardware, software, and materials science, combined with United Therapeutics renowned expertise in regenerative medicine has enabled advances in lung modeling, 3D printing, as well as material formulation using a unique rhCollagen, and material handling to yield significant capabilities in bioprinters and biomaterials for lung manufacturing. As a result, 3D Systems has built a portfolio of unique capabilities specifically designed to address the requirements of regenerative medicine applications. The newly developed Print to Perfusion process enables 3D printing of high-resolution scaffolds which can be perfused with living cells to create tissues. The ability to print large, vascularized, highly detailed hydrogel scaffolds at rapid speeds is now opening new opportunities for a range of tissue applications. To advance these efforts, 3D Systems is expanding its high-speed Figure 4 technology through innovation tailored to bioprinting and regenerative medicine. Building upon these capabilities, the company in collaboration with its partners will be able to advance innovation into numerous applications within the human body. The company also believes these capabilities have the potential to enable novel laboratory testing methods to accelerate the development of new drug therapies while reducing the need for animal testing.

Over the last years as bioprinting and regenerative medicine have evolved, weve seen a growing need to place cells at high-resolution in a nurturing matrix to produce complex tissues, said Chuck Hull, co-founder, executive vice president and chief technology officer, 3D Systems. Precise 3D printing with hydrogels, followed by perfusion of cells into the printed scaffold is the best way to achieve this, and we are thankful our work with United Therapeutics has given us the opportunity to advance and perfect this technology.

Our collaboration with 3D Systems has allowed us to take a first-principles approach to regenerative medicine, said Derek Morris, associate director of engineering, Lung Biotechnology PBC. The full size, vascularized lung scaffolds produced by 3D Systems printers allow our cellularization teams to focus on our mission to build an unlimited supply of transplantable organs.

Building on the progress the company has made to date, 3D Systems is infusing additional resources into its regenerative medicine R&D efforts to accelerate development programs that expand on the scope of potential applications. The company intends to add additional regenerative medicine domain expertise to its team, complementing the deep technology experience and expertise focused on these advanced applications. Additionally, the company is growing its roster of partners to broaden the portfolio of solutions the company offers. 3D Systems previously announced collaborations with CollPlant Biotechnologies (NASDAQ:CLGN) and Antleron that expanded its capabilities in regenerative medicine.

CollPlant is the developer of proprietary recombinant human collagen (rhCollagen) BioInk technology, which is also being used in collaboration with United Therapeutics. Bringing together 3D Systems expertise in 3D printing and healthcare and CollPlants expertise in rhCollagen-based BioInks will enable joint development of tissue and scaffold bioprinting processes for thirdparty collaborators. As a result, the companies are jointly addressing an unmet market need for a comprehensive solution to produce tissues and scaffolds for regenerative medicine applications.

Antleron co-creates, as an innovation pioneer in the field of regenerative medicine, personalized manufacturing solutions for advanced therapy applications. Antleron integrates core technologies such as 3D printing, bioreactors, and artificial intelligence with bioprocess know-how to enable disruptive manufacturing workflows that convert cells into living therapies. The 3D Systems/Antleron partnership wants to make 3D printing an integrated part of modular and digital factory-of-the-future solutions to enable sustainable and personalized manufacturing of cell & gene therapies, vaccines, tissues, and organs.

3D Systems has delivered additive manufacturing solutions to the healthcare industry for more than 25 years. The company is renowned for its VSP surgical planning solutions which have enabled the planning of more than 140,000 patient-specific surgical cases, as well as the production of more than two million medical devices from its operations in Littleton, Colorado, and Leuven, Belgium. 3D Systems NextDent 5100 digital dentistry solution is recognized as the industry leader in transforming prosthodontic and orthodontic production at dental laboratories and clinics. The company also has a long-standing relationship with Align Technology, Inc., the makers of Invisalign clear aligners, iTero scanners, and exocad CAD/CAM services, for which it has co-developed proprietary solutions comprised of customized hardware, software, and non-aligner materials that are used to mass-produce more than 500,000 unique patient-specific aligners per day.

Commenting on the future of regenerative medicine at 3D Systems, Dr. Jeffrey Graves, president and CEO, said, The progress that Chuck Hull and his team have made over the last three years, in collaboration with the Team from United Therapeutics, has been absolutely remarkable. Through unique developments in new printer hardware, software, and biomaterials technology, they have laid the foundation needed for accelerated commercialization of bioprinting at 3D Systems. Taking a strong application focus we will now expand our commercialization efforts in this nascent industry, which we believe will experience significant growth over the next decade. We expect these efforts to bring substantial benefits to the healthcare patients in critical need, both through direct applications within the human body, as well as in accelerating the development of drug therapies in the pharmaceutical industry. We anticipate regenerative medicine to be an exciting growth driver for our healthcare business over the next decade.

Forward-Looking StatementsCertain statements made in this release that are not statements of historical or current facts are forward-looking statements within the meaning of the Private Securities Litigation Reform Act of 1995. Forward-looking statements involve known and unknown risks, uncertainties and other factors that may cause the actual results, performance or achievements of the company to be materially different from historical results or from any future results or projections expressed or implied by such forward-looking statements. In many cases, forward-looking statements can be identified by terms such as "believes," "belief," "expects," "may," "will," "estimates," "intends," "anticipates" or "plans" or the negative of these terms or other comparable terminology. Forward-looking statements are based upon managements beliefs, assumptions, and current expectations and may include comments as to the companys beliefs and expectations as to future events and trends affecting its business, including with respect to the development, expansion and commercialization of new technology, and are necessarily subject to uncertainties, many of which are outside the control of the company. The factors described under the headings "Forward-Looking Statements" and "Risk Factors" in the companys periodic filings with the Securities and Exchange Commission, as well as other factors, could cause actual results to differ materially from those reflected or predicted in forward-looking statements. Although management believes that the expectations reflected in the forward-looking statements are reasonable, forward-looking statements are not, and should not be relied upon as a guarantee of future performance or results, nor will they necessarily prove to be accurate indications of the times at which such performance or results will be achieved. The forward-looking statements included are made only as of the date of the statement. 3D Systems undertakes no obligation to update or review any forward-looking statements made by management or on its behalf, whether as a result of future developments, subsequent events or circumstances or otherwise.

About 3D Systems More than 30 years ago, 3D Systems brought the innovation of 3D printing to the manufacturing industry. Today, as the leading additive manufacturing solutions partner, we bring innovation, performance, and reliability to every interaction - empowering our customers to create products and business models never before possible. Thanks to our unique offering of hardware, software, materials, and services, each application-specific solution is powered by the expertise of our application engineers who collaborate with customers to transform how they deliver their products and services. 3D Systems solutions address a variety of advanced applications in healthcare and industrial markets such as medical and dental, aerospace & defense, automotive, and durable goods. More information on the company is available at http://www.3dsystems.com.

A photo accompanying this announcement is available at https://www.globenewswire.com/NewsRoom/AttachmentNg/638523c6-d22a-4f35-8cd8-4c4783a32e48

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3D Systems Announces Breakthrough in Bioprinting Technology and Expansion of Regenerative Medicine Initiative - GlobeNewswire

Over the next 10 years, gene therapies are expected come into their own as a treatment option for a variety of diseases. So far, two such therapies have snagged regulatory approval, Novartis Zolgensma for spinal muscular atrophy, and Sparks Luxturna for a rare form of genetic blindness. More are waiting their turn.

Multiple companies are delving into gene therapy research with hopes of developing a one-time treatment for devastating genetic diseases. Gene therapies offer great reward in the form of treating various devastating diseases, but there are also significant risks. Over the past year, several clinical studies have been halted or scrapped due to safety concerns.

Bay Area-based Audentes Therapeutics had a temporary hold placed on the gene therapy under development for X-linked myotubular myopathy following reports of several patient deaths. That hold has since been lifted by the U.S. Food and Drug Administration. Uniqure also saw a hold placed on its hemophilia B trial after a patient in the study developed liver cancer. The hold was placed weeks after the company announced promising Phase III results at a conference in December.

Despite those risks, hundreds of millions of dollars in research dollars are being invested in gene therapies because of the potential near-curative capabilities the technology could offer. In December, life sciences giant Bayer launched a cell and gene therapy platform within its pharmaceutical division in order to become a leading company within a rapidly emerging and evolving field that offers the potential of life-saving therapies. Eli Lilly also dove into the field in December with the acquisition of Prevail Therapeutics. That deal was expected to extend Eli Lillys research efforts through the creation of a gene therapy program that will be anchored by Prevail's portfolio of clinical-stage and preclinical neuroscience assets.

This week, German scientists reported they were able to use gene therapy to help paralyzed mice run again. The researchers were able to genetically engineer a unique protein dubbed hyper-interleukin-6, which was then able to stimulate the regeneration of nerve cells in the visual system. A few weeks after the treatment, the injured animals were able to walk again.

Scientists in China announced the development of a gene therapy that could potentially reverse the effects of ageing. Initial research was conducted with mice, but if it is proven to be safe, human testing could begin. As Reuters reported, the method involved inactivating a gene called kat7 which the scientists found to be a key contributor to cellular ageing. Researchers used CRISPR/Cas9 to screen thousands of genes for those which were particularly strong drivers of cellular senescence, the term used to describe cellular ageing, Reuters said.

Earlier this month, a public-private partnership in Boston formed to open a new facility to boost advances in cell and gene therapies. This creation of this new facility is being helmed by Harvard University and the Massachusetts Institute of Technology. Those prestigious universities are partnering with industry members such as Fujifilm Diosynth Biotechnologies, Cytivia and Alexandria Real Estate Equities, as well as multiple research hospitals. Part of the goal of this new institute, which is still unnamed at this point, is to boost the supply of materials for research and early clinical studies, provide space for some research and also offer training in equipment used for gene therapies, The Harvard Gazette reported this week.

On Monday, Curadigm, a subsidiary of France-based Nanobiotix, forged a collaboration with Sanofi to assess if that companys Nanoprimer technology is a promising option to significantly improve gene therapy development. The goal of the project is to establish proof-of-concept for the Nanoprimer as a combination product that could improve treatment outcomes for gene therapy product candidates.

Many promising nucleic acid-based therapeutics administered intravenously are limited in their efficacy due to rapid clearance in the liver, which prevents these therapies from reaching the necessary accumulation in target tissues to generate their intended outcomes. Additionally, accumulation in the liver, rather than in the target tissues, can lead to dose-limiting hepatic toxicity, Nanobiotix said in its announcement. The Nanoprimer is designed to precisely and temporarily occupy therapeutic clearance pathways in the liver. Delivered intravenously, immediately prior to the recommended therapy, the technology acts to prevent rapid clearancethereby increasing bioavailability and subsequent accumulation of therapeutics in the targeted tissues.

The Nanoprimer is a combination product candidate that does not alter or modify the therapies it is paired with, which means if the research with Sanofi is successful, Curadigm could seek out other opportunities for its technology.

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Study finds site of immune surveillance of the brain, points to new ways to target brain inflammation

Immune cells (yellow and purple) fill a sinus (teal) in the outer layer of the meninges, the tissue that surrounds the brain and spinal cord. Researchers at Washington University School of Medicine in St. Louis have found that immune cells stationed in such sinuses monitor the brain and initiate an immune response if they detect a problem.

Alzheimers disease, multiple sclerosis, autism, schizophrenia and many other neurological and psychiatric conditions have been linked to inflammation in the brain. Theres growing evidence that immune cells and molecules play a key role in normal brain development and function as well. But at the core of the burgeoning field of neuroimmunology lies a mystery: How does the immune system even know whats happening in the brain? Generations of students have been taught that the brain is immunoprivileged, meaning the immune system largely steers clear of it.

Now, researchers at Washington University School of Medicine in St. Louis believe they have figured out how the immune system keeps tabs on whats going on in the brain. Immune cells are stationed in the meninges the tissue that covers the brain and spinal cord where they sample fluid as it washes out of the brain. If the cells detect signs of infection, disease or injury, they are prepared to initiate an immune response to confront the problem, the researchers said.

The findings, published Jan. 27 in the journal Cell, open up the possibility of targeting immune cells at such surveillance sites as a means of treating conditions driven by brain inflammation.

Every organ in the body is being surveilled by the immune system, said senior authorJonathan Kipnis, PhD, the Alan A. and Edith L. Wolff Distinguished Professor of Pathology & Immunology. If theres a tumor, an injury, an infection anywhere in the body, the immune system has to know about it. But people say the exception is the brain; if you have a problem in the brain, the immune system just lets it happen. That never made sense to me. What weve found is that there is indeed immune surveillance of the brain its just happening outside the brain. Now that we know where its happening, that opens up lots of new possibilities for modulating the immune system.

In 2015, Kipnis and colleagues found a network of vessels that drains fluid and small molecules from the brain into the lymph nodes, where immune responses are initiated. The discovery demonstrated a direct physical connection between the brain and the immune system. But the network of vessels represented an exit from the brain. It remained unclear where immune cells entered or surveilled the brain.

Kipnis and Justin Rustenhoven, PhD, a postdoctoral researcher and the first author on the new paper, set out to find the immune systems gateway to the brain. They saw a clue in the fact that the vessels containing fluid leaving the brain run alongside sinuses in the dura mater, the tough outer layer of the meninges just underneath the skull. Dural sinuses, which contain blood that carries immune cells, lack the tight barrier that elsewhere keeps blood separate from the brain.

Experiments showed that the dural sinuses were packed with molecules from the brain and immune cells that had been carried in with blood. Multiple kinds of immune cells were represented, including some that pick up and display suspect molecules from the blood and others that scan the suspect molecules and respond to them by mounting a defense.

Imagine if your neighbors went through your trash every day, said Kipnis, also a professor of neurosurgery, of neurology and of neuroscience. If they start finding blood-stained towels in your trash, they know something is wrong. Its the same thing with the immune system. If patrolling immune cells see tumor antigens or signs of infection from the brain, the cells know theres a problem. They will take that evidence to immune headquarters, which is the lymph nodes, and initiate an immune response.

The findings suggest that the immune system surveils the brain from a distance and only enters when it finds a problem. This could explain why the brain was thought for so long to be immunoprivileged.

Immune activity in the brain can be highly detrimental, Rustenhoven said. It can kill neurons and cause swelling. The brain cant tolerate much swelling because the cranium is a fixed volume. So immune surveillance is pushed to the borders, where the cells can still monitor the brain but dont risk damaging it.

Multiple sclerosis is a degenerative condition in which the immune system attacks the protective sheath on nerves, causing communication problems between the brain and the rest of the body. The cause is unknown. Using a mouse model of multiple sclerosis, the researchers showed that initiation of disease triggered a massive accumulation of activated immune cells in the dural sinuses, suggesting that harmful immune responses may begin in the dura mater and spread to the brain.

Further work is needed to verify the role of dural sinuses in neuroinflammatory conditions. But the location of the sinuses just on the inside of skull on the accessible side of the blood-brain barrier suggests possibilities for targeting the immune system in that area.

If this is a gateway to the brain, we can attempt to manipulate the area with therapies aimed at preventing over-activated immune cells from entering the brain, Kipnis said. The dura is close to the surface, so we may even be able to deliver drugs through the skull. In theory, you could come up with an ointment that diffuses through the skull bone and reaches the dura. We might have found where inflammatory responses for many neuroimmunological conditions start, and theres so much we can do with that.

Rustenhoven J, Drieu A, Mamuladze T, Alves de Lima K, Dykstra T, Wall M, Papadopoulos Z, Kamamori M, Salcador A, Baker W, Lemieux M, Da Mesquita S, Cugurra A, Fitzpatrick J, Sviben S, Kossina R, Bayguinov P, Townsend R, Zhang Q, Gilmore PE, Smirnov I, Lopes MB, Herz J, Kipnis J. Functional characterization of the dural sinuses as a neuroimmune interface. Cell. Jan. 27, 2020. DOI: 10.1016/j.cell.2020.12.040

This work was supported by the National Institute on Aging of the National Institutes of Health (NIH), grant numbers AG034113, AG057496 and AT010416; and the BEE Consortium from Cure Alzheimers Fund.

Washington University School of Medicines 1,500 faculty physicians also are the medical staff of Barnes-Jewish and St. Louis Childrens hospitals. The School of Medicine is a leader in medical research, teaching and patient care, ranking among the top 10 medical schools in the nation by U.S. News & World Report. Through its affiliations with Barnes-Jewish and St. Louis Childrens hospitals, the School of Medicine is linked to BJC HealthCare.

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Jan. 26, 2021 10:00 UTC

NEW YORK & AMSTERDAM--(BUSINESS WIRE)-- Neogene Therapeutics, Inc., a pre-clinical stage biotechnology company pioneering a new class of fully personalized neo-antigen T cell therapies to treat cancer, today announced that the companys co-founder, Board member and Chairman of its Scientific Advisory Board, Ton Schumacher, Ph.D., has been awarded the 2021 Jeantet-Collen Prize for Translational Medicine. Awarded each year by the Louis-Jeantet Foundation to leading-edge researchers who are active in the member states of the Council of Europe, the prize is intended to foster scientific excellence and encourage the continuation of innovative research projects.

Throughout his distinguished career, Ton has taken a technology-based approach to analyze and engineer the activity of immune cells in cancer, which has inspired the development of different novel neoantigen-directed cancer therapies. We are delighted that he has been selected for the prestigious Jeantet-Collen prize based on his groundbreaking research and considerable contributions to scientific innovation in cancer treatment, said Carsten Linnemann, Ph.D., President, Chief Executive Officer and Co-Founder of Neogene Therapeutics. Tons seminal research laid the groundwork for Neogenes proprietary platform, which our team is using to pioneer a new class of fully personalized T cell therapies to treat patients with solid tumors.

Dr. Schumacher was awarded the 2021 Jeantet-Collen Prize for Translational Medicine for his work in developing technologies to study the role of the immune system in cancer progression and improve the diagnosis and treatment of cancer. As a recipient of this prize, he will receive funds to continue his research to further understand the immune microenvironment during tumor transition and predict which tumor antigens are recognized by T cells, potentially leading to the development of novel diagnostics and therapeutics.

Dr. Schumacher currently serves as Principal Investigator at The Netherlands Cancer Institute in Amsterdam; a member of the Oncode Institute, a virtual Dutch cancer research institute; and Professor of Immunotechnology at Leiden University Medical Center. Previously, he co-founded AIMM Therapeutics, Neon Therapeutics and T Cell Factory, and served as Chief Scientific Officer of Kite Pharma EU. Dr. Schumacher is an internationally renowned immunologist and researcher in the areas of cancer neo-antigens and T cell receptor (TCR) therapies. In recognition of his work in these areas, he has received, among others, the Amsterdam Inventor Award, the Queen Wilhelmina Cancer Research Award, the Meyenburg Cancer Research Award, the William B. Coley Award, and the Stevin Award of the Dutch Research Council.

About Neogene Therapeutics

Neogene Therapeutics, Inc. is a pre-clinical stage biotechnology company pioneering the development of next-generation, fully personalized engineered T cells therapies for a broad spectrum of cancers. The companys engineered T cells target mutated proteins found in cancer cells due to cancer-associated DNA mutations, or neo-antigens, that render tumor cells vulnerable to detection by T cells. Neogenes proprietary technology platform aims to identify TCR genes with specificity for neo-antigens from tumor biopsies. Neogenes novel approach intends to deliver a tailored set of TCR genes for each individual patient, which will be engineered into patient-derived T cells directing them towards neo-antigens in tumor cells, with the goal of providing a fully personalized engineered T cell therapy for cancer.

For more information, please visit http://www.neogene.com, and follow Neogene Therapeutics on LinkedIn.

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Neogene Therapeutics Announces Ton Schumacher, Ph.D., Company Co-Founder, Awarded 2021 Jeantet-Collen Prize for Translational Medicine - BioSpace

What do we currently know about the effects of SARS-CoV-2 on the brain? In this feature, we round up the emerging evidence.

How does SARS-CoV-2, the virus that causes COVID-19, affect the human brain? Recent studies have given us clues, shedding light on why COVID-19 can be so severe for some people and why the symptoms can last a long time.

There is a long history of similar viruses affecting the brain, researchers have pointed out, so many expect the new coronavirus to have this effect.

For example, Dr. Gabriel A. de Erausquin, a professor of neurology at The University of Texas Health Science Center at San Antonio, notes that Since the flu pandemic of 1917 and 1918, many of the flu-like diseases have been associated with brain disorders.

Those respiratory viruses included H1N1 and SARS-CoV. The SARS-CoV-2 virus, which causes COVID-19, is also known to impact the brain and nervous system, adds the researcher. The question is how, and to what extent?

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Dr. de Erausquin recently published a paper along with colleagues, including senior author Dr. Sudha Seshadri, a professor of neurology at the same institution and director of the universitys Glenn Biggs Institute for Alzheimers and Neurodegenerative Diseases.

The basic idea of our study is that some of the respiratory viruses have affinity for nervous system cells, Prof. Seshadri explains. She adds, Olfactory cells are very susceptible to viral invasion and are particularly targeted by SARS-CoV-2, and thats why one of the prominent symptoms of COVID-19 is loss of smell.

Olfactory cells are concentrated in the nose. Through them, the virus reaches the olfactory bulb in the brain, which is located near the hippocampus, a brain area involved in short-term memory.

The trail of the virus, when it invades the brain, leads almost straight to the hippocampus, explains Dr. de Erausquin. That is believed to be one of the sources of the cognitive impairment observed in COVID-19 patients. We suspect it may also be part of the reason why there will be an accelerated cognitive decline over time in susceptible individuals.

In their paper, the scientists refer to existing evidence that makes them particularly wary of SARS-CoV-2s impact on the brain. For example, researchers have found that:

By 2022, the authors plan to have learned more about how COVID-19 affects the brain. A consortium of researchers from over 30 countries funded by the Alzheimers Association will conduct concerted research into the neurological effects of the novel coronavirus.

Study participants will be recruited from a pool of millions of people with COVID-19, in addition to some already enrolled in international studies. The researchers will take key measures of brain health using MRI scans and assessments of brain volume, cognition, and behavior initially and at 6, 9, and 18 months of the study.

The aim is to understand how having COVID-19 increases the risk, severity, and progression of neurodegenerative conditions, such as Alzheimers, or psychiatric conditions, such as depression.

Other research adds to the concerns expressed by Dr. de Erausquin, Dr. Seshadri, and their colleagues specifically regarding the risk of delirium and coma.

A new study appearing in The Lancet Respiratory Medicine found a much higher rate of these outcomes among COVID-19 patients than what is usual among patients with acute respiratory failure.

The authors of this study looked at 2,088 COVID-19 patients admitted to 69 adult ICUs across 14 countries. They found that about 82% of the patients were in a coma for an average of 10 days, and 55% had delirium for an average of 3 days. On average, acute brain dysfunction, manifested as a coma or delirium, lasted for 12 days.

This is double what is seen in non-COVID ICU patients, explains co-first study author Brenda Pun, an advanced care nurse at the Vanderbilt University Medical Centers Division of Allergy, Pulmonary, and Critical Care Medicine, in Nashville, TN. Pun is also the director of data quality at the Vanderbilt Critical Illness, Brain Dysfunction, and Survivorship Center.

The study was observational, so it could not draw conclusions about the causes of these rates of acute brain dysfunction. However, the authors speculate that strong sedatives and reduced family visitations may both play a role.

The research showed that patients who had received benzodiazepine sedative infusions which act as a depressant for the nervous system were 59% more likely to develop delirium. The study also found that patients who had received in-person or virtual family visitations were 30% less likely to develop delirium.

The authors caution that because of the pressures of the pandemic, many healthcare professionals have reverted to older practices, while newer protocols have clear provisions in place for avoiding acute brain dysfunction.

It is clear in our findings that many ICUs reverted to sedation practices that are not in line with best practice guidelines, says Pun, and were left to speculate on the causes. Many of the hospitals in our sample reported shortages of ICU providers informed about best practices.

There were concerns about sedative shortages, and early reports of COVID-19 suggested that the lung dysfunction seen required unique management techniques including deep sedation. In the process, key preventive measures against acute brain dysfunction went somewhat by the boards.

These prolonged periods of acute brain dysfunction are largely avoidable. Our study sounds an alarm: As we enter the second and third waves of COVID-19, ICU teams need, above all, to return to lighter levels of sedation for these patients, frequent awakening and breathing trials, mobilization, and safe in-person or virtual visitation.

senior study author Dr. Pratik Pandharipande, a professor of anesthesiology at Vanderbilt University Medical Center

Other researchers have focused on how the new coronavirus infects neurons and damages brain tissue.

For example, a team led by Akiko Iwasaki, the Waldemar Von Zedtwitz Professor of Immunobiology and Molecular, Cellular, and Developmental Biology at the Yale School of Medicine, in New Haven, CT, used lab-grown, miniature 3D organ reproductions to analyze how SARS-CoV-2 invades the brain.

The study, which appears in the Journal of Experimental Medicine, showed that the new coronavirus was able to infect neurons in these lab-grown organoids and replicate itself by boosting the metabolism of infected cells. Simultaneously, healthy, uninfected neurons in the vicinity died as their oxygen supply was cut off.

The researchers also determined that blocking the ACE2 receptors prevented the virus from infecting the human brain organoids.

The scientists also analyzed the effects of SARS-CoV-2 on the brains of mice genetically modified to produce human ACE2 receptors. Here, the virus altered the brains vasculature, or blood vessels. This could, in turn, cut off the brains oxygen supply.

Furthermore, the mice with an infection that had spread to the brain had much more severe illness than those with an infection limited to the lungs.

Lastly, Prof. Iwasaki and her team examined the postmortem brains of three patients who died from COVID-19. They found SARS-CoV-2 in the cortical neurons of one of the three. The infected areas were associated with ischemic infarcts, wherein a limited blood supply caused tissue damage and cell death. All three patients had microinfarcts in their brains.

Our study clearly demonstrates that neurons can become a target of SARS-CoV-2 infection, with devastating consequences of localized ischemia in the brain and cell death. [] Our results suggest that neurologic symptoms associated with COVID-19 may be related to these consequences and may help guide rational approaches to the treatment of COVID-19 patients with neuronal disorders.

co-corresponding author Dr. Kaya Bilguvar, director of the Yale Center for Genome Analysis

Another study supports the idea that COVID-19s attack on the brain is what makes the disease very severe.

A team of researchers, including senior study author Mukesh Kumar, a virologist specializing in emerging infectious diseases and assistant professor at Georgia State University, in Atlanta, infected the nasal passages of mice with the new coronavirus. This caused severe illness in the rodents, even after the infection had cleared from their lungs.

The scientists then analyzed levels of the virus in several organs, comparing the intervention group of mice with a control group, which had received a dose of saline solution instead of the virus.

The results published in the journal Viruses revealed that viral levels in the lungs peaked around day 3 after the infection, but levels in the brain persisted on days 5 and 6, coinciding with the symptoms being most severe and debilitating.

The scientists also found that the brain contained 1,000 times higher levels of the virus than other parts of the body.

This may explain, the senior researcher says, why some people seem to recover after a few days and have improved lung function, only to then relapse and have more severe symptoms, some of which can prove lethal.

Our thinking that [COVID-19 is] more of a respiratory disease is not necessarily true, Kumar says. Once it infects the brain, it can affect anything because the brain is controlling your lungs, the heart, everything. The brain is a very sensitive organ. Its the central processor for everything.

The brain is one of the regions where viruses like to hide, he continues, because unlike the lungs, the brain is not as equipped, from an immunological perspective, to clear viruses.

Thats why were seeing severe disease and all these multiple symptoms like heart disease, stroke, and all these long-haulers with loss of smell, loss of taste, explains the senior researcher. All of this has to do with the brain, rather than with the lungs.

Kumar cautions that the brain damage may mean that many people with COVID-19 continue to be at high risk of neurodegenerative diseases, such as Parkinsons, multiple sclerosis, or general cognitive decline, after recovering.

Its scary. [] A lot of people think they got COVID, and they recovered, and now theyre out of the woods. Now I feel like thats never going to be true. You may never be out of the woods.

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COVID-19 and the brain: What do we know so far? - Medical News Today