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Neural top–down control of physiology concerns the direct regulation by the brain of physiological functions (in addition to smooth muscle and glandular ones). Cellular functions include the immune system’s production of T-lymphocytes and antibodies, and nonimmune related homeostatic functions such as liver gluconeogenesis, sodium reabsorption, osmoregulation, and brown adipose tissue ...
Health risk behaviors, such as poor eating habits and obesity, physical inactivity, substance use, and sleep deprivation are also considered to be risk factors of allostatic load. [29] Extended activation of the hypothalamic-pituitary-adrenal axis (HPA), as well as the autonomic nervous system, can lead to negative impacts on biological health.
The nervous and endocrine systems often act together in a process called neuroendocrine integration, to regulate the physiological processes of the human body. Neuroendocrinology arose from the recognition that the brain, especially the hypothalamus , controls secretion of pituitary gland hormones, and has subsequently expanded to investigate ...
Polyvagal theory combines ideas from evolutionary biology and neurology, to claim that autonomic reactions have adapted to the phylogenetic development of neural circuits. [14] It claims that the sympathetic nervous system, and two distinct branches of the parasympathetic nervous system, are phylogenetically ordered and activated for responses ...
This places homeostasis as a function within allostasis; however, some argue it is a larger paradigm altogether. [14] Allostasis redefines health and disease beyond the stable measures from lab tests or blood pressure, for example; and expands it to define health as the flexibility of these values.
In biology, the nervous system is the highly complex part of an animal that coordinates its actions and sensory information by transmitting signals to and from different parts of its body. The nervous system detects environmental changes that impact the body, then works in tandem with the endocrine system to respond to such events. [1]
There are two types of functional systems: System of the first type provide homeostasis due to internal (existing) resources of the body, inside its boundaries (e.g. blood pressure). System of a second type supports homeostasis due to a change of behavior, interaction with the outside world and are the basis of different types of behavior.
In neuroscience, homeostatic plasticity refers to the capacity of neurons to regulate their own excitability relative to network activity. The term homeostatic plasticity derives from two opposing concepts: 'homeostatic' (a product of the Greek words for 'same' and 'state' or 'condition') and plasticity (or 'change'), thus homeostatic plasticity means "staying the same through change".