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Scientific Program
26th International Conference on Neuropharmacology and Neurochemistry, will be organized around the theme “”
Neuropharmaceutics 2021 is comprised of 30 tracks and 5 sessions designed to offer comprehensive sessions that address current issues in Neuropharmaceutics 2021.
Submit your abstract to any of the mentioned tracks. All related abstracts are accepted.
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Neurochemistry and Neuropharmacology is the learning of how drugs distress cellular function in the nervous system, and the neural mechanisms through which they impact behavior. There are two key branches of neuropharmacology are behavioral and molecular. Behavioral neuropharmacology emphases on the learning of how drugs affect human behavior (neuro psychopharmacology), with the study of how drug requirement and addiction affect the human brain.
- Track 1-1Clinical Pharmacology
- Track 1-2Pharmacognosy
- Track 1-3Pharmacodynamics and Pharmacokinetics
- Track 1-4NEURAL CONTROL OF MUSCLE
- Track 1-5Neurochemical Bases of Drug Abuse
- Track 1-6Neurochemical Transmission
- Track 1-7Neurogenesis in the Hippocampus
Molecular and Cellular Neuroscience prints unique research of high significance covering all aspects of neurosciences specified by the broadest interpretation of the journal's title. In specific, the journal emphases on synaptic maintenance, de-organization and re-organization, neuron-glia communication, and de-/regenerative neurobiology. In accumulation, studies using animal models of disease with translational prospects and experimental methods with backward validation of disease signatures from human patients are welcome.
- Track 2-1Neurocellular Anatomy
- Track 2-2Intercellular Signaling
- Track 2-3Intracellular Signaling
- Track 2-4Cell Membrane Structures and Functions
Neurological disorders are pathologically well-defined as disorders that affect the brain as well as the nerves found throughout the human body and the spinal cord. There are many abnormalities happens in the brain: Structural, biochemical or electrical, spinal cord or other nerves can result in a range of symptoms.
- Track 3-1Chronic neurological disorders (CND)
- Track 3-2Chronic neurodegenerative diseases
- Track 3-3Spinal Cord Disorders
- Track 3-4Attention deficit hyperactive disorder
- Track 3-5Hallucinogen Persisting Perception Disorder
- Track 3-6Mild Cognitive Impairment
Stroke is the most common reason of death and the leading source of acquired neurologic handicap. The clinical neurophysiology of stroke emphases on slow EEG potentials recorded in stroke. A clinical neurophysiologist is a neurologist who focuses in the diagnosis of nervous system disorders. Neurophysiologists do EEG (electroencephalography), EMG (electromyography), and other actions to calculate the function of the brain and nervous system.
- Track 4-1Repetitive stimulation
- Track 4-2Visual evoked potentials
- Track 4-3Electroretinography
- Track 4-4Polysomnography
- Track 4-5Ischemic stroke
- Track 4-6Transient ischemic attack (TIA)
- Track 4-7Thrombotic Stroke
- Track 4-8Subarachnoid Stroke
Alzheimer's and Parkinson's are both neurological illnesses and these diseases are affected by damaged brain cells. In both circumstances can involve dementia, besides depression, anxiety, and sleep disturbances. These diseases can lead to psychotic symptoms such as delusions and hallucinations. Alzheimer's disease has clumps of two main proteins are beta-amyloid and tau. Clumps of beta-amyloid are termed plaques, and tau clumps are termed tangles. Parkinson's disease has Lewy bodies in main areas of the brain that control movement and Lewy bodies are collected of the protein alpha-syncline.
- Track 5-1Amyloid Hypothesis
- Track 5-2Down syndrome
- Track 5-3Neuro Psychiatry of Parkinson Disease
- Track 5-4Clinical Diagnostics of Parkinson Disease
Neuroimmunology is a branch that combines neuroscience and neuroscience is the study of the nervous system and immunology is the study of the immune system. Neuroimmunologists discovers better understanding in the relations of these two complex systems during development, homeostasis and response to injuries. The most common neurological infections are: An inflammation of the brain and Encephalitis that can be created by either bacteria or virus. Meningitis is the inflammation of the membranes that enclose the brain and spinal cord, can be created by either bacteria or virus.
- Track 6-1Fungal infections
- Track 6-2Parasitic infections
- Track 6-3Prion diseases
- Track 6-4Bacterial infections such as Lyme disease, tuberculosis, syphilis
- Track 6-5Brain abscess
Traumatic brain injury is a misfortune of various causes, pathologies, and extremely varied and often multifaceted clinical presentations. Because of its preference for brain systems underlying cognitive and multifaceted behavioural operations, it may cause chronic and severe psychiatric illness that needs expert management. Traumatic brain injury is a typical for other neuropsychiatric disorders and may serve as an incubator of new thoughts for neurodegenerative disease.
- Track 7-1Traumatic brain injury (TBI)
- Track 7-2Acquired brain injury
- Track 7-3Sensation and perception
- Track 7-4Motivated behaviour (hunger, thirst, sex)
- Track 7-5Sleep and biological rhythms
Neuropharmacology is the learning of the effects of drugs on the nervous system and targeting to develop compounds to benefit humans with psychiatric and neurological disease. These contain Huntington's disease, myotonic dystrophy, Rett syndrome and fragile X syndrome. In these cases, the single-gene mutation causes certain neurons in the central and peripheral nervous system to develop abnormally and function poorly.
- Track 8-1Gene therapy of inherited neurological disorders
- Track 8-2Immune challenges to gene transfer into the brain
- Track 8-3Rett syndrome and fragile X syndrome
- Track 8-4Single-gene mutation
- Track 8-5Ataxia
- Track 8-6Charcot-Marie-Tooth disease
Cognitive neuroscience is the learning of how the brain enables the mind. Cognitive science uses the experimental approaches of cognitive psychology and artificial intelligence to create and test models of higher-level cognition such as thought and language. Cognitive neuroscience is study cognition from the level of cranial nerve and is a significant field of learning science. It is main focus on the neural mechanisms of perception, selective attention, memory, language, emotion and consciousness.
- Track 9-1Social cognition
- Track 9-2Change blindness
- Track 9-3Cognitive Psychology
- Track 9-4Clinical Psychology
- Track 9-5Counselling Psychology
Central nervous system diseases are also known as central nervous system disorders are a group of neurological disorders that affect the structure or function of the brain or spinal cord, which collectively form the central nervous system. Brain and nervous system problems are common. These neurological disorders include multiple sclerosis, Alzheimer's disease, Parkinson's disease, epilepsy, and stroke, and can affect memory and ability to perform daily activities.
- Track 10-1Amyotrophic lateral sclerosis (ALS)
- Track 10-2Headache and Stroke
- Track 10-3Seizures and Dementia
- Track 10-4Multiple sclerosis (MS)
The advances in artificial intelligence systems can contribute to advancing neuroscience and revealing brain secrets. This provides for better models for the simulation of the human brain by neuroscientists and researchers. Neural networks act as "virtual brains" that capture our brain's representation. The link between artificial intelligence and neuroscience can lead to an understanding of the brain mechanisms that generate human awareness.
- Track 11-1AI in neurology: oncology
- Track 11-2AI in neurology: neurodegeneration
- Track 11-3AI in neurology: neurovascular
- Track 11-4AI in neurology: traumatic brain injury
- Track 11-5AI in neurology: spinal cord injury
The maintenance of neuroscience databases is facilitated by neuroinformatics. The area is related to development of analytical tools and computer models for the sharing of data, the integration of knowledge and the examination of neuroscience big data. Computational neuroscience includes the study by computer modelling and mathematical analysis of brain function. In computer scientists, they carry out research in which data is collected and computer models are created based on the brain's electric models and biological functions.
- Track 12-1Brain–computer interfaces
- Track 12-2Neural computation
- Track 12-3Neurobiologically inspired evolutionary systems
- Track 12-4Neural signal processing
Brain mapping is a series of neuroscience methods based on mapping (biological) amounts or properties to (human or non-human) space representations of the brain that produce maps. Brain mapping helps doctors understand a problem's source better. Knowing a problem source permits specific therapies. The anatomy of the brain is properly understood. Brain mapping gives information on brain and connectivity communication.
- Track 13-1Magnet resonance imaging
- Track 13-2Cortical and subcortical brain mapping
- Track 13-3Electroencephalography (EEG)
- Track 13-4Magnetoencephalography (MEG)
- Track 13-5Regional cerebral blood flow
- Track 13-6Regional metabolic rate of glucose
Therapies for brain stimulation use directly with electricity to activate or inhibit the brain. Strom can be directly determined by electrodes implanted in the brain or by electrodes placed non-invasively on the scalp. Electricity can also be induced through the use of magnetic fields on the head. Brain imagery and brain stimulation have both enhanced our understanding of normal functional mechanisms and changes related to brain and mental illness. Brain encouragement has also shown promise to reduce brain and mental illness symptoms and allows hypotheses derived from data on brain imaging to be tested.
- Track 14-1Positron emission tomography
- Track 14-2Deep brain stimulation
- Track 14-3Transcranial magnetic stimulation therapy
- Track 14-4Functional magnetic resonance imaging
Neurogenesis is the process through which neuronal stem cells are produced (NSCs). It takes place in all animal species except proliferous animals (sponges) and placozoans. The process of neurogenesis is the formation of new neurons in the brain. In certain brain areas after birth and throughout our lifetime, neurogenesis is essential when an embryo develops.
- Track 15-1New Tools Offer a Clearer Picture of Neurogenesis
- Track 15-2Adult neurogenesis
- Track 15-3Neurogenesis in the Olfactory Epithelium
- Track 15-4Neurogenesis in the Subventricular Zone and Rostral Migratory Stream
Neurotherapy teaches a person to produce better EEG patterns with positive strength. The customer is connected to EEG sensors that measure brain activity during a neurofeedback session. Connect the sensors to a computer, and the EEG signals control simple computer games. A type of alternative therapy, specifically one type of biofeedback that uses real-time electromephalography (EEG) displays to illustrate brain activity, is neurotherapy also known as neurofeedback (NFB), EEG biofeedback, or brainwave education.
- Track 16-1Chemical & biological therapeutic
- Track 16-2Cytokine-based therapies
- Track 16-3Implementation of mindfulness-based therapies
- Track 16-4Transcranial magnetic stimulation therapy
- Track 16-5Gene therapy
- Track 16-6Stem-cell therapy
- Track 16-7Advances in migraine therapeutics
The three principal parts of the brain are the Cerebrum, and brainstem. The cerebrum consists of the right and left hemispheres and is the largest portion of the brain. It performs higher functions such as touch interpretation, vision and hearing, as well as speech, thought, emotion, learning and control of the movement. In the human body, the brain is the most important organ. It controls and coordinates actions and reacting, allows us to think and feel, and enables us, all things that make us human, to have memories and feelings.
- Track 17-1Cerebrum, cerebellum and brainstem
- Track 17-2Gross anatomy
- Track 17-3Microanatomy
- Track 17-4Physiology
- Track 17-5Comparative anatomy
The presynaptic neuron is the information sending cell (i.e., transmits chemical messages). The postsynaptic neuron is the information cell (i.e., receives chemical messages). PNs are inhibited indirectly by presynaptic inhibition, which regulates the probability of ORN-PN releases, while the postsynaptic inhibition directly inhibits PN activity by hyperpolarizing the membrane potential of PNs. The physiological difference between the PNs is pre- and postsynaptic inhibition.
- Track 18-1Transmission at chemical synapses
- Track 18-2Excitatory and inhibitory postsynaptic potentials
- Track 18-3Spatial and temporal summation
- Track 18-4Signal termination
- Track 18-5Electrical synapses
Synapse formation is a highly regulated process which leads to the transmission and receipt of signals in morphologically separate subcellular structures at pre- and post-synaptic sites. A neurotransmitter receptor is a class of receptors that binds neurotransmitters specifically in contrast to other molecules. Neurotransmitter receptors receive signals in post synaptic cells that trigger electric signal by regulating ion channel activity.
- Track 19-1Types of neurotransmitter receptors
- Track 19-2Conventional neurotransmitters
- Track 19-3Small molecule neurotransmitters
- Track 19-4Metabotropic receptors
- Track 19-5Neuropeptides
Synaptic dysfunction results in cell-intrinsic molecular mechanism modifications or changes in surrounding biochemical processes. A synaptic dysfunction at an early or late stage is a common denominator of several diseases called synaptopathies. Synaptopathy is a popular term used to define the key characteristics of the psychiatric and neurodegenerative diseases. It suggests that synaptic disorders can be the major determinant of such brain diseases.
- Track 20-1Dysregulated synaptic
- Track 20-2Complex neuropsychiatric disorders
- Track 20-3Autism spectrum disorder (ASD)
- Track 20-4Schizophrenia
- Track 20-5Genome-wide association study
The hypothesis of the synaptic plasticity and memory asserts that the activity-dependent synaptic plasticity is induced during memory formation at appropriate synapse and is both essential and sufficient to encode and store the kind of memory mediated by the brain area in which it is observed. Memories are first stored in the hippocampus, where in seconds of the events to be remembered, synapses between excitatory neurons begin to develop new circuits. A relatively small number of synapses can increase its strength by binding neurons into a circuit that stores a new memory.
- Track 21-1Long-term potentiation
- Track 21-2Dopamine
- Track 21-3MEMORY HYPOTHESIS
- Track 21-4Anterograde alterations
- Track 21-5Retrograde alterations
- Track 21-6Artificial engram
Pathology is the knowledge of disease or damage causes and effects. Pathology highlights disease elements: source, growth methods (pathogenesis), structural cell changes and alterations result. Oncology teaches neoplasms of the backbone and brains, most of which are very frightful and life-threatening (astrocytoma, glioma, glioblastoma multiform, ependymoma, pontine glioma, and brain stem tumours are among the most examples of these). Glioma of brainstem and pons, multiform Glioblastoma and high-grade (highly anaplastic) Astrocytoma are among the worst among malignant cancers of the brain.
- Track 22-1Pathophysiology of Intracranial Tumors
- Track 22-2Pathogenesis
- Track 22-3Diagnosis and staging
- Track 22-4Signs and symptoms
After nervous system injury neural stem cells provide the possibility of replacing the lost tissue. Stem cells may, partly by secreting growth factors, encourage host neural repair, and their regeneration-promoting activities may be altered through gene delivery. Stem cells are unique human cells, which can develop into many different types of cells. This can vary between muscle cells and brain cells. In certain cases, damaged tissues can also be repaired. Neural stem cells can replace lost tissue after injury to the nervous system. The host neural repair can be enhanced by stem cells partly through secreting growth factors and gene supply can modify their regeneration promotions.
- Track 23-1Totipotent (or Omnipotent) Stem Cells
- Track 23-2Pluripotent Stem Cells
- Track 23-3Multipotent Stem Cells
- Track 23-4Oligopotent Stem Cells
- Track 23-5Unipotent Stem Cells
NBB continues to innovate by using advanced imaging techniques to examine the extraordinary abilities of the mind. The faculty leads students to learn how the brain produces memories, thoughts, emotions and awareness. The brain is a meeting place between our genes and the environment where nature interacts and nurtures. It can affect our intellectual circuitry and biochemistry, as well as genetic controls. In turn, these neurobiological mechanisms can affect conduct.
- Track 24-1Levels of Behavioral Causation
- Track 24-2The Neural Bases of Operant Conditioning
- Track 24-3Perception of Stimuli
- Track 24-4Innate and Learned Behaviour
Innovative and trustworthy reports on functional recovery from neurological injury and long-standing neurological care are provided by Neurorehabilitation and Neural Repair. The main focus of neurological rehabilitation is on disability. In many ways, neurological rehabilitation differs from other neurological branches. Rehabilitation is the education process of a person with a disability, which is aimed at helping him or her to cope as independently as possible with family, friends, work and leisure.
- Track 25-1Cortical remodeling after stroke
- Track 25-2Mechanisms of sprouting and regeneration
- Track 25-3Traumatic brain injury or spinal cord injury
- Track 25-4Multidisciplinary management of neurologic disease
- Track 25-5Biomedical engineering
Neuroendocrinology is the biologic branch (in particular the physiological one) which study the interplay between the nervous system and the endocrine system. In a process called neuroendocrine integration, nervous and endocrine systems often work together to regulate the physiological processes of the human body. The recognition that the brain controls the secretion of hypophysical hormones, especially the hypothalamus, and subsequently expanded to explore numerous interconnections between endocrine and nervous systems, led to a neuroendocrinology.
- Track 26-1Pediatric Endocrinology
- Track 26-2Cardiovascular Endocrinology
- Track 26-3Behavioural endocrinology
- Track 26-4Neuroendocrine tumor
- Track 26-5Neuroendocrine cell
- Track 26-6Neuroendocrine system
Children with diseases and conditions which affect the nervous system are diagnosed and treated by paediatric neurologists. Patients with head injuries, seizures or muscle weakness are also included. Epilepsy is a chronic disease causing recurring seizures without provocation. An attack is a sudden rush of brain electrical activity. Two major types of convulsions are present. Widespread convulsions affect the entire brain. Only one part of the brain is affected by focal or partial seizures.
- Track 27-1Seizures and epilepsy
- Track 27-2Headaches migraines and concussions
- Track 27-3Muscular dystrophies
- Track 27-4Cerebral palsy
- Track 27-5Behavioural disorders, including ADHD, Tourette syndrome, and sleep problems
Neuroimaging is a technology class which provides an array of structural anatomy and physiological or metabolic functions within the central and peripheral nervous system, directly or indirectly derived from visual representation. The technology of the neuroimaging—for example, CT, MRI, FMRI and positron emission tomography (PET)—provides both anatomical and functional nervous system visualisation, which is a major advancement in modern medicine and the science of neuroscience. The methods of neuro-imaging include: neuroimaging.
- Track 28-1Neuroimaging techniques
- Track 28-2Recent advancements
- Track 28-3Magnetic resonance imaging
- Track 28-4Magnetoencephalography
- Track 28-5Cranial Ultrasounds
Neuromodulation is defined as a field of science, medicine and bioengineering, comprising both implantable and implantable electronic and chemical technologies, impacting on neural interfaces, to enhance life for humanity by the International Neuromodulation Society (INS).
- Track 29-1Neuromodulation for Chronic Pain
- Track 29-2Brain Neuromodulation
- Track 29-3Functional Electrical Stimulation (FES)
- Track 29-4Neuromodulation and GI Disorders
- Track 29-5Neuromodulation for Urological Disorders
- Track 29-6Neuromodulation for Cardiac Disorders
- Track 29-7Neuromodulation for Spasticity
The brain is one of the most active organs in the body metabolically. The brain stores no excess energy and derives almost all its energy requirements from aerobic glucose oxidation. It thus calls for continuous glucose and oxygen supply to comply with its energy demands. In most of the organ of the body, blood flow is closely associated with the metabolism of the tissue. An increase in tissue metabolism, such as during muscle contraction or changes in brain neural activity, leads to increased blood flow (active hyperaemia).
- Track 30-1Glucose utilization and brain imaging
- Track 30-2Measurement of local glucose utilization
- Track 30-3Functional Activation of Energy Metabolism
- Track 30-4Brain Disorders and Metabolism
- Track 30-5Functional MRI