The present disclosure relates generally to the field of neurology. In particular, the disclosure relates to a method of detecting a neurodegenerative disease in a subject and methods of treatment thereof. The methods include detecting the level of an exosome-bound aggregated biomarker in a sample obtained from the subject, wherein an increased level of the exosome-bound aggregated biomarker as compared to a reference indicates that the subject is suffering from a neurodegenerative disease. Also described are methods for detecting a subject at risk of developing amyloidosis or a neurodegenerative disease, methods for detecting and treating amyloidosis or a neurodegenerative disease in a subject, and methods of determining the aggregation state of a biomarker in a sample.

The present invention includes methods and kits for the diagnosing a neurological disease within primary care settings comprising: obtaining a blood test sample from a subject, measuring IL-7 and TNFα biomarkers in the blood sample, comparing the level of the one or a combination of biomarkers and neurocognitive screening tests with the level of a corresponding one or combination of biomarkers in a normal blood sample and neurocognitive screening tests, and predicting that an increase in the level of the blood test sample in relation to that of the normal blood sample indicates that the subject is likely to have a neurological disease.

Provided are compositions and methods for differentiating and diagnosing ischemic stroke and subgroups thereof (e.g., cardioembolic stroke, large vessel stroke, atherothrombotic stroke, lacunar stroke) from intracerebral hemorrhage.

The present invention discloses an application of a β3 adrenergic receptor (ADRB3) as a marker for detecting a plurality of diseases, and an application of anti-human ADRB3 monoclonal antibody in diagnosing a disease and preparing a drug for treating the disease. The present invention finds through research that the ADRB3 is a key receptor in nerve-endocrine-immunoregulatory network, and an ADRB3-mediated signaling pathway regulates proliferation and differentiation of neutrophils, lymphocytes and tumor cells. Under normal circumstances, the ADRB3 maintains the non-specific immunocompetence and specific immunocompetence of an organism, and eliminates pathogenic microorganisms and aged organism tissues to play a role in protecting the organism and anti-aging. Under pathological conditions, excessive activation of the signaling pathway will cause systemic chronic inflammation, and destroy immune homeostasis. Therefore, the ADRB3 can be used as a diagnostic marker and a therapeutic target for a plurality of diseases. Anti-human ADRB3 antibody can specifically bond with the ADRB3, regulate the activity of the ADRB3, has the functions of resisting cancer, inflammation, poisoning, shock, allergy, viral infection, autoimmune disease, disease caused by regenerative dysfunction, autoimmune disease, cachexia, cardiovascular and cerebrovascular disease, neurodegenerative disease and aging, regulating autophagy, treating aging disease, etc., and has important medical value and research and application prospects.

The invention relates to using serum exosomal proteins, α-synuclein and clusterin, as biomarkers in the prediction and identification of a subject having Parkinson's Disease, and provides methods for determining their levels. The biomarkers are also useful for monitoring, prevention and/or treatment of Parkinson's Disease and in differentiating Parkinson's disease from atypical parkinsonian syndromes including MSA.

The present invention refers to a new site-specific monoclonal antibody for tau protein and its use as a tool in specific biomarkers. It also discloses the process of generating said site-specific monoclonal antibody, and kits for early detection of neurodegenerative diseases and pathologies involved with the tau protein, such as Alzheimer's and other types of dementia.

The present disclosure provides yeast screening system/s and methods for screening of candidate therapeutic compound/s for treating, at least one proteniopathy and/or protein misfolding disorder. More specifically, the present disclosure provides systems and methods for identifying a therapeutic compound that inhibit Hcy fibril formation and uses thereof in treating Alzheimer's disease.

Among the various aspects of the present disclosure is the provision of a noninvasive and localized brain liquid biopsy using focused ultrasound. Briefly, therefore, the present disclosure is directed to methods and systems to identify brain lesion or tumor characteristics without the need for a solid brain biopsy.

A method of diagnosing central nervous system injuries such as acquired brain injury (ABI) and/or acquired spinal cord injury (ASI), including mild TBI (concussion or blast wave), mild ASI (contusion, stretch or partial cord transection), non-TBI brain injury and/or non-TSI spinal cord injury in a subject (animal or human). The method includes (a) obtaining a biological test sample from the subject, identifying metabolites in the subject's sample using metabolomics thereby obtaining a subject's metabolite matrix and generating a subject's profile using the patient's metabolite matrix; and (b) using multivariate statistical analysis and machine learning to compare the subject's profile with predetermined set of profiles of CNS injuries and a predetermined set of profiles of controls to determine if the subject has a CNS injury.

Antibodies exhibiting a specific genetically modified signature associated with certain diseases of the central nervous system, like multiple sclerosis (MS) and clinically isolated syndrome have been identified. These antibodies recognize and bind with certain tissues in the brain and central nervous system and thus are useful as therapeutics, in the production of animal disease models, targets for therapies and as part of assays of the central nervous system.