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Avian influenza virus prevention in the domestic host by a deactivated vaccine
Abstract Influenza viruses, which affect both birds and mammals, pose a substantial public health concern. An estimated 10% of the global population annually becomes infected, resulting in 300,000 to 600,000 deaths worldwide. Our research objectives are to develop a Hemagglutinin (HA) and Neuraminidase (NA) based rabies-vectored vaccine against highly pathogenic Avian Influenza (HPAI) A virus H5N1. We have already demonstrated the vaccine’s immunogenicity and protective efficacy against HPAI H5N1 Vietnam 1203. To advance this research, we propose to utilize a novel RAVB-based deactivated vaccine that harbors the H5 antigens of the current homologous circulation (clade 2.3.4.4b) and a construct expressing N1. Our first aim will involve comparing the H5 or H5/N1 RABV-based vaccines against challenges by PR8 recombinants carrying H5N1 proteins in mice. We will employ a single immunization and a prime/boost approach, either with or without an adjuvant approved for use in animals and humans (SEPIVAC SWE™). We will assess the role of T cells in the vaccine-induced protection by performing CD4/CD8 depletion before challenge Our second aim will utilize the vaccine approach identified to protect our mouse system in dairy cows. Subsequently, we will assess the vaccine’s efficacy against challenges administered intranasally and intramammary. We will verify the role of the vaccine-induced antibodies in protection against H5N1 by performing passive transfer studies of purified IgG from vaccinated cows before challenge. In summary, this study will evaluate the efficacy and delineate the mechanism of protection of a safe and well- established vaccine platform to protect against HPAI H5 and explore its potential as an animal and human vaccine.
An intranasal non-opioid treatment for opioid use disorder
Emerging Treatment Options in Psychiatry
The World Health Organization (WHO) estimates that untreated mental disorders accountfor 13% of the total global burden of disease, and by 2030, depression alone will be the leadingcause of disability around the world – outpacing heart disease, cancer, and HIV. This grim pictureis further compounded by the mental health burden delivered by the coronavirus pandemic.The lack of novel treatment options in psychiatry is restricted by a limited understanding in theneuroscience basis of mental disorders, availability of relevant biomarkers, poor predictability inanimal models, and high failure rates in psychiatric drug development. However, theannouncement in 2019 from the Federal Drug Administration (FDA) for approvals of newinterventions for treatment-resistant depression (intranasal esketamine) and postpartumdepression (i.v. brexanolone), demand critical attention. Novel public-private partnerships indrug discovery, new translational data on co-morbid biology, in particular the ascendance ofpsycho-immunology, have highlighted the arrival of a new frontier in biological psychiatryresearch for depressive disorders.
INTRANASAL LEMON-DERIVED NANOVESICLES AMELIORATE COGNITIVE IMPAIRMENT IN A HIGH-FAT DIET RAT MODEL OF METABOLIC SYNDROME: FOCUS ON MODULATORY HIPPOCAMPAL SIGNALING PATHWAYS
FENS Forum 2026
INTRANASAL EFFECTS OF GALANIN 1-15 ON MOOD DISORDERS AND ALCOHOL SELF-ADMINISTRATION IN RATS
FENS Forum 2026
Five-week intranasal nerve growth factor treatment is safe and favors brain neurogenesis
Intranasal administration of mesenchymal stem-cells-secretome improves neurological deficits induced by perinatal asphyxia: a preclinical study
Intranasal Delivery of Galanin 2 and Neuropeptide Y1 Agonists Enhanced Spatial Memory Performance and antidepressant effects through Neuronal Precursor Cells Proliferation in the hippocampus
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