Anatomical study with clinical significance of communicating and visceral branching of the cervical and upper thoracic sympathetic trunk.

Current advances in the management of the autonomic nervous system in various cardiovascular diseases, and in treatments for pain or sympathetic disturbances in the head, neck, or upper limbs, necessitate a thorough understanding of the anatomy of the cervicothoracic sympathetic trunk. Our objective was to enhance our understanding of the origin and distribution of communicating branches and visceral cervicothoracic sympathetic nerves in human fetuses. This was achieved through a comprehensive topographic systematization of the branching patterns observed in the cervical and upper thoracic ganglia, along with the distribution of communicating branches to each cervical spinal nerve. We conducted detailed sub-macroscopic dissections of the cervical and thoracic regions in 20 human fetuses (40 sides). The superior and cervicothoracic ganglia were identified as the cervical sympathetic ganglia that provided the most communicating branches on both sides. The middle and accessory cervical ganglia contributed the fewest branches, with no significant differences between the right and left sides. The cervicothoracic ganglion supplied sympathetic branches to the greatest number of spinal nerves, spanning from C5 to T2 . The distribution of communicating branches to spinal nerves was non-uniform. Notably, C3 , C4 , and C5 received the fewest branches, and more than half of the specimens showed no sympathetic connections. C1 and C2 received sympathetic connections exclusively from the superior ganglion. Spinal nerves that received more branches often did so from multiple ganglia. The vertebral nerve provided deep communicating branches primarily to C6 , with lesser contributions to C7 , C5 , and C8 . The vagus nerve stood out as the cranial nerve with the most direct sympathetic connections. The autonomic branching pattern and connections of the cervicothoracic sympathetic trunk are significantly variable in the fetus. A comprehensive understanding of the anatomy of the cervical and upper thoracic sympathetic trunk and its branches is valuable during autonomic interventions and neuromodulation. This knowledge is particularly relevant for addressing various autonomic cardiac diseases and for treating pain and vascular dysfunction in the head, neck, and upper limbs.

Remote ischemic preconditioning prevents sarcolemmal-associated proteolysis by MMP-2 inhibition.

The death of myocytes occurs through different pathways, but the rupture of the plasma membrane is the key point in the transition from reversible to irreversible injury. In the myocytes, three major groups of structural proteins that link the extracellular and intracellular milieus and confer structural stability to the cell membrane: the dystrophin-associated protein complex, the vinculin-integrin link, and the spectrin-based submembranous cytoskeleton. The objective was to determine if remote ischemic preconditioning (rIPC) preserves membrane-associated cytoskeletal proteins (dystrophin and ß-dystroglycan) through the inhibition of metalloproteinase type 2 (MMP-2) activity. A second objective was to describe some of the intracellular signals of the rIPC, that modify mitochondrial function at the early reperfusion. Isolated rat hearts were subjected to 30 min of global ischemia and 120 min of reperfusion (I/R). rIPC was performed by 3 cycles of ischemia/reperfusion in the lower limb (rIPC). rIPC significantly decreased the infarct size, induced Akt/GSK-3 ß phosphorylation and inhibition of the MPTP opening. rIPC improved mitochondrial function, increasing membrane potential, ATP production and respiratory control. I/R increased ONOO- production, which activates MMP-2. This enzyme degrades ß-dystroglycan and dystrophin and collaborates to sarcolemmal disruption. rIPC attenuates the breakdown of ß-dystroglycan and dystrophin through the inhibition of MMP-2 activity. Furthermore, we confirm that rIPC activates different intracellular pathway that involves the an Akt/Gsk3ß and MPTP pore with preservation of mitochondrial function.

Innervation of the heart: Anatomical study with application to better understanding pathologies of the cardiac autonomics.

Current advances in management of the cardiac neuroaxis in different cardiovascular diseases require a deeper knowledge of cardiac neuroanatomy. The aim of the study was to increase knowledge of the human fetal extrinsic cardiac nervous system. We achieved this by systematizing the origin and formation of the cardiac nerves, branches, and ganglia and their sympathetic/parasympathetic connections. Thirty human fetuses (60 sides) were subjected to detailed sub-macroscopic dissection of the cervical and thoracic regions. Cardiac accessory ganglia lying on a cardiac nerve or in conjunction with two or more (up to four) nerves before entering the mediastinal cardiac plexus were observed in 13 sides. Except for the superior cardiac nerve, the sympathetic cardiac nerves were individually variable and inconstant. In contrast, the cardiac branches of the vagus nerve appeared grossly more constant and invariable, although the individual cardiac branches varied in number and position of origin. Each cervical cardiac nerve or cardiac branch of the vagus nerve could be singular or multiple (up to six) and originated from the sympathetic trunk or the vagus nerve by one, two, or three roots. Sympathetic nerves arose from the cervical-thoracic ganglia or the interganglionic segment of the sympathetic trunk. Connections were found outside the cardiac plexus. Some cardiac nerves were connected to non-cardiac nerves, while others were connected to each other. Common sympathetic/parasympathetic cardiac nerve trunks were more frequent on right (70%) versus left sides (20%). The origin, frequency, and connections of the cardiac nerves and branches are highly variable in the fetus. Detailed knowledge of the normal neuroanatomy of the heart could be useful during cardiac neuromodulation procedures and in better understanding nervous pathologies of the heart.

A Step Further-The Role of Trigeminocardiac Reflex in Therapeutic Implications: Hypothesis, Evidence, and Experimental Models.

The trigeminocardiac reflex (TCR) is a well-recognized brainstem reflex that represents a unique interaction between the brain and the heart through the Vth and Xth cranial nerves and brainstem nuclei. The TCR has mainly been reported as an intraoperative phenomenon causing cardiovascular changes during skull-base surgeries. However, it is now appreciated that the TCR is implicated during non-neurosurgical procedures and in nonsurgical conditions, and its complex reflex pathways have been explored as potential therapeutic options in various neurological and cardiovascular diseases. This narrative review presents an in-depth overview of hypothetical and experimental models of the TCR phenomenon in relation to the Vth and Xth cranial nerves. In addition, primitive interactions between these 2 cranial nerves and their significance are highlighted. Finally, therapeutic models of the complex interactions of the TCR and areas for further research will be considered.

Chronic exposure to polluted urban air aggravates myocardial infarction by impaired cardiac mitochondrial function and dynamics.

Air pollution exposure positively correlates with increased cardiovascular morbidity and mortality rates, mainly due to myocardial infarction (MI). Herein, we aimed to study the metabolic mechanisms underlying this association, focusing on the evaluation of cardiac mitochondrial function and dynamics, together with its impact over MI progression. An initial time course study was performed in BALB/c mice breathing filtered air (FA) or urban air (UA) in whole-body exposure chambers located in Buenos Aires City downtown for up to 16 weeks (n = 8 per group and time point). After 12 weeks, lung inflammatory cell recruitment was evident in UA-exposed mice. Interestingly, impaired redox metabolism, characterized by decreased lung SOD activity and increased GSSG levels and NOX activity, precede local inflammation in this group. At this selected time point, additional mice were exposed to FA or UA (n = 12 per group) and alveolar macrophage PM uptake and nitric oxide (NO) production was observed in UA-exposed mice, together with increased pro-inflammatory cytokine levels (TNF-α and IL-6) in BAL and plasma. Consequently, impaired heart tissue oxygen metabolism and altered mitochondrial ultrastructure and function were observed in UA-exposed mice after 12 weeks, characterized by decreased active state respiration and ATP production rates, and enhanced mitochondrial H2O2 production. Moreover, disturbed cardiac mitochondrial dynamics was detected in this group. This scenario led to a significant increase in the area of infarcted tissue following myocardial ischemia reperfusion injury in vivo, from 43 ± 3% of the area at risk in mice breathing FA to 66 ± 4% in UA-exposed mice (n = 6 per group, p < 0.01), together with a sustained increase in LVEDP during myocardial reperfusion. Taken together, our data unravel cardiac mitochondrial mechanisms that contribute to the understanding of the adverse health effects of urban air pollution exposure, and ultimately highlight the importance of considering environmental factors in the development of cardiovascular diseases.

Infarto de miocardio en un modelo murino de hiperactividad simpática cardíaca / Myocardial Infarction in a Murine Model of Cardiac Sympathetic Hyperactivity

RESUMEN Introducción: La disautonomía es uno de los mecanismos fisiopatológicos principales que marcan el pronóstico de la cardiopatía isquémica y la insuficiencia cardíaca. La búsqueda de nuevas oportunidades de tratamiento requiere un conocimiento más profundo de los efectos cardíacos de la activación simpática crónica. Objetivos: Estudiar el tamaño del infarto y la función ventricular izquierda en un modelo de ratones transgénicos con sobreexpresión de la proteína Gs-α cardíaca en el contexto de la isquemia/reperfusión miocárdica y el infarto crónico. Material y métodos: Ratones transgénicos (TG) con sobreexpresión cardíaca de la subunidad alfa de la proteína Gs y sus respectivos controles wild-type (WT) fueron sometidos a isquemia miocárdica regional de 30 minutos con 2 horas de reperfusión (IR) o un infarto sin reperfusión (I) de 28 días de evolución. Se cuantificó el tamaño del infarto (TI) con cloruro de 2,3,5-trifeniltetrazolio y se evaluó la función ventricular izquierda mediante ecocardiografía y estudio hemodinámico. Cada grupo experimental estuvo acompañado por un grupo control (WT / TG Sham-2hrs y WT / TG Sham-28d). Resultados: No hubo diferencias significativas en el TI luego de la IR entre los ratones TG y WT (57,3 ± 3,5% vs 59,2±2,5%, respectivamente, p = NS). La frecuencia cardíaca en los ratones TG fue mayor durante el desarrollo de todo el protocolo. Con la infarto se observó un descenso de la fracción de eyección (WT: Sham-28d: 82 ± 2,4% vs I-28d: 44 ± 4% y TG: Sham-28d 89 ± 2% vs I-28d 42 ± 3%; p <0,05) conjuntamente con una disminución de la fracción de acortamiento (FA), y los cambios del área fraccional (CAF) del ventrículo izquierdo (VI) en comparación con los valores basales y sus respectivos grupos controles. Sin embargo, no se observaron diferencias entre los grupos WT y TG. Conclusión: la sobreexpresión de la proteína Gs-α cardíaca no aumenta el tamaño del infarto ni modifica la función ventricular izquierda en la isquemia/reperfusión aguda y en el infarto crónico en comparación con sus respectivos controles

ABSTRACT Background: Dysautonomia is one of the main pathophysiological mechanisms that define the prognosis of ischemic heart disease and heart failure. The search for new treatment opportunities requires a deeper understanding of the cardiac effects of chronic sympathetic activation. Objective: The aim of this study was to analyze left ventricular infarct size and ventricular function in a transgenic mouse model with overexpression of the cardiac Gs-α protein, in the context of myocardial ischemia/reperfusion and chronic infarction. Methods: Transgenic mice (TG) overexpressing cardiac Gs-α and its wild-type variant (WT) were subjected to 30-minute regional myocardial ischemia followed by 2-hour reperfusion (IR) or non- reperfusion (I) with a 28-day follow-up period. Infarct size (IS) was quantified using 2,3,5-triphenyltetrazolium chloride and left ventricular function was evaluated by echocardiography and LV catheterization. Each experimental group was accompanied by a control group (WT/TG Sham-2hrs and WT/TG Sham-28d). Results: There were no significant differences in IS after IR between TG and WT mice (57.3 ± 3.5% vs. 59.2 ± 2.5%, respectively, p = NS). The heart rate in TG mice was higher throughout the experiment. With ischemia, a in ejection fraction (WT: Sham-28d: 82 ± 2.4% vs. I-28d: 44 ± 4% and TG: Sham-28d 89 ± 2% vs. I-28d 42 ± 3%; p <0.05) was observed together with a decrease in shortening fraction and left ventricular fractional area changes compared with baseline values and their respective control (Sham) groups. However, no differences were observed between the WT and TG groups. Conclusions: Cardiac Gs-α protein overexpression does not increase infarct size or modify left ventricular function in acute ischemia / reperfusion and chronic infarction compared with their respective controls.

Mimetización del precondicionamiento por activación vagal. Efectos sobre la función ventricular en un modelo experimental crónico / Mimicking Preconditioning by Vagal Stimulation. Effectis on Ventricular Function in a Chronic Experimental Model

RESUMEN Introducción: En trabajos previos demostramos que la electroestimulación vagal preisquémica (EVp) es capaz de reducir el tamaño del infarto agudo de miocardio, sin una mejoría significativa sobre la función ventricular dentro de las dos horas de reperfusión. Se desconocen los efectos de esta modalidad de EV sobre la función ventricular izquierda (FVI) a largo plazo. Objetivos: Estudiar si los efectos protectores de la EVp breve sobre el tamaño del infarto agudo repercuten en una mejoría de la FVI en un modelo crónico de isquemia y reperfusión miocárdica. Material y métodos: En ratones FVB se realizó una isquemia miocárdica regional de 45 minutos con 2 horas o 28 días de seguimiento posreperfusión, con o sin 10 minutos de EV preisquémica. Se midió el tamaño del infarto (TI) con cloruro de 2,3,5-trifeniltetrazolio. Se evaluó la FVI mediante ecocardiografía y cateterismo del VI. Resultados: La EVp redujo el TI medido a las 2 horas de reperfusión de 66,8 ± 3,2% a 43,2 ± 1,6% (p < 0,001), sin una respuesta favorable sobre la FVI. A los 28 días, en el grupo con EVp se observó una mejoría en la FVI, evidenciada por una menor presión de fin de diástole del ventrículo izquierdo (4,44 ± 1 vs. 6,91 ± 1 mmHg del grupo control; p < 0,05), mayor fracción de eyección (69,7 ± 2,8% vs. 59 ± 3,2%; p < 0,05), mayor fracción de acortamiento (33,4 ± 2,23% vs. 25,8 ± 1,8%; p < 0,05) y menor tiempo de relajación isovolúmica (25 ± 0,8 mseg vs. 30,3 ± 1,2 mseg; p < 0,05). Conclusiones: En un modelo de isquemia y reperfusión miocárdica en ratones, la mimetización del precondicionamiento isquémico por EV mejora la evolución crónica del infarto y redunda en una mayor recuperación de la FVI.

ABSTRACT Background: Previous studies have shown that preischemic vagal electrostimulation (pVS) reduces acute myocardial infarct size, without a significant improvement on ventricular function within the two-hour reperfusion period. It is unknown which are the long-term effectis of pVS on left ventricular function (LVF). Objectives: The aim of this study was to analyze whether the protective effectis of brief pVS on acute infarct size improves LVF in a chronic myocardial ischemia-reperfusion model. Methods: FVB mice were subjected to 45-minutes regional myocardial ischemia followed by 2 hours of reperfusion or 28-day post-reperfusion follow-up with or without 10-minutes pVS. Infarct size (IS) was measured with 2,3,5-triphenyltetrazolium chloride, and LVF was assessed by echocardiography and left ventricular catheterization. Resultis: Preischemic vagal stimulation reduced IS from 66.8±3.2% to 43.2±1.6% (p <0.001) at 2 hours of reperfusion, without a favorable LVF response. At 28 days, the pVS group exhibited LVF improvement, with lower left ventricular end-diastolic pressure (4.44±1 vs. 6.91±1 mmHg in the control group; p<0.05), higher ejection fraction (69.7±2.8% vs. 59.3±3.2; p<0.05), greater shortening fraction (33.4±2.23 vs. 25.8±1.8%; p<0.05) and lower isovolumic relaxation time (25±0.8 ms vs. 30.3 ±1.2 ms; p<0.05) Conclusions: In a mice model of myocardial ischemia and reperfusion, mimicking ischemic preconditioning by VS improves the chronic outicome of infarction, resulting in greater LVF recovery.