Respiratory viruses are associated with more severe symptoms and complications in diabetic subjects. We hypothesize that the diabetic neuropathy could provide a significant contribution to risk of disease severity. The diabetic neuropathy and the autonomic dysfunction might determine the loss of immune response regulation and contribute to reduction of pulmonary function, in particular gas exchange.

Preliminary data highlight how the immune system reaction causes a lung damage during COVID-19 infection. The exaggerated cytokine production, which currently represents the most interesting therapeutic target, is a pathophysiological mechanism shared with other severe acute respiratory infections, such as SARS and MERS [1]. T-lymphopenia is usually detectable in COVID-19 patients, caused by consumption of CD4 + and CD8 + lymphocytes and decrease in regulatory T cells, with a loss of suppression of inappropriate immune response. Moreover, a higher serum concentration of pro-inflammatory cytokines (TNF-alpha, IL-6) and chemokines (Il-8) is frequently found in severe forms of COVID-19 [2]. These data suggest a role for the inflammatory response in the development of severe complications of the disease.

Nervous system regulates innate and adaptive immunity through a mechanism called the inflammatory reflex. The autonomic nervous system receives sensory inputs from inflammatory cells and modulates the immune response by a negative feedback mechanism. Humoral or neural signals can activate the sensory afferent arc of the reflex. TNF-alpha and the other inflammatory mediators can gain access to central nervous system through circumventricular organs, which are characterized by discontinuities of blood–brain barrier. Furthermore, sensory innervation of immune organs by ascending vagus fibres can send afferent signals to the reflex. The motor efferent arc of the reflex releases acetylcholine in the reticuloendothelial system, leading to decrease in production of pro-inflammatory cytokines in macrophages [2]. Diabetic neuropathy could play a more important role in the loss of capacity to regulate immune response, since some physiological mechanisms could be impaired with a consequent overexpressed response to inflammatory stimuli. Our hypothesis is that the dysfunction of the autonomic nervous system, reflecting an imbalance between sympathetic and parasympathetic modulation, could affect the pro-inflammatory state in diabetic patients with COVID-19, as a consequence of a dysregulation of the inflammatory reflex.

Regarding lung function, we showed a significant association between autonomic nervous system dysfunction and reduced DLCO in type 1 diabetes [1]. One of the most frequently described histopathological pulmonary alterations in diabetes is the thickening of the pulmonary capillary basal laminae and of the alveolar epithelium, which correlates with the severity of microvascular complications [1]. An increase in collagen protein synthesis and accelerated cross-linking, induced by reactive oxygen species-induced oxidative stress, together with non-enzymatic protein glycation in the extracellular matrix, seems to cause injury in the pulmonary microcirculation by increasing vessel wall thickening. However, we found that DLCO significantly correlated with HRV (heart rate variability), even after adjustment for clinical and metabolic variables, such as microvascular complications [3]. A possible explanation is that diabetic autonomic neuropathy could induce functional alterations in the regulation of pulmonary bronchomotor tone as well as in the control of ventilation [4]. In another study, we reported changes in bronchomotor tone among diabetic patients, who showed a faster clearance of I123 MIBG during ventilatory scintigraphy, as a result of noradrenergic dysfunction in bronchial innervation [5].

Therefore, in this setting it might be useful to investigate the correlation between severity of COVID-19 pneumonia and diabetic autonomic neuropathy to confirm our hypothesis and support the finding of a different management.