Evolutionary pressure produced 2 master regulators of physiological homeostasis: the nervous system and the immune system. The nervous system evolved to integrate physiological functions and control changes in homeostasis. Neural signals establish reflex responses, perceive disturbances in the environment (internal or external), and elicit activation of the afferent arc (ie, the neural circuit that transfers information from the periphery to the brain). The central nervous system integrates these messages and transduces an output signal through the efferent arc, which conveys the reflex response to the innervated system, which can modulate organ functions. The immune system is the body’s defense against infection or sterile tissue injury; when challenged by disturbances deriving from the exterior or interior milieu, it has the task of balancing inflammation in the affected organ. Whatever the threat to homeostasis, immunity orchestrates complex responses comprising an initial defense phase that typically entails tissue destruction followed by a reparative phase. However, in some conditions, resolution of the destructive phase fails, and excessive inflammation can trigger ongoing damage and aberrant immune responses. Although interaction between these 2 evolutionarily highly conserved systems is long recognized, characterized even in ancient species, investigation into pathophysiological mechanisms regulating their reciprocal cross-talk has been the object of pathbreaking immunology and neuroscience research only in recent decades. This is particularly the case of cardiovascular biology.
Heart, Spleen, Brain / Carnevale, Daniela; Lembo, Giuseppe. - In: CIRCULATION. - ISSN 1524-4539. - 138:18(2018), pp. 1917-1919. [10.1161/CIRCULATIONAHA.118.035628]
Heart, Spleen, Brain
Carnevale, Daniela
;Lembo, Giuseppe
2018
Abstract
Evolutionary pressure produced 2 master regulators of physiological homeostasis: the nervous system and the immune system. The nervous system evolved to integrate physiological functions and control changes in homeostasis. Neural signals establish reflex responses, perceive disturbances in the environment (internal or external), and elicit activation of the afferent arc (ie, the neural circuit that transfers information from the periphery to the brain). The central nervous system integrates these messages and transduces an output signal through the efferent arc, which conveys the reflex response to the innervated system, which can modulate organ functions. The immune system is the body’s defense against infection or sterile tissue injury; when challenged by disturbances deriving from the exterior or interior milieu, it has the task of balancing inflammation in the affected organ. Whatever the threat to homeostasis, immunity orchestrates complex responses comprising an initial defense phase that typically entails tissue destruction followed by a reparative phase. However, in some conditions, resolution of the destructive phase fails, and excessive inflammation can trigger ongoing damage and aberrant immune responses. Although interaction between these 2 evolutionarily highly conserved systems is long recognized, characterized even in ancient species, investigation into pathophysiological mechanisms regulating their reciprocal cross-talk has been the object of pathbreaking immunology and neuroscience research only in recent decades. This is particularly the case of cardiovascular biology.| File | Dimensione | Formato | |
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