ABSTRACT
SARS-CoV-2 (Severe Acute Respiratory Syndrome Coronavirus-2) affects the central nervous system (CNS), which is shown in a significant number of patients with neurological events. In this study, an updated literature review was carried out regarding neurological disorders in COVID-19. Neurological symptoms are more common in patients with severe infection according to their respiratory status and divided into three categories: (1) CNS manifestations; (2) cranial and peripheral nervous system manifestations; and (3) skeletal muscle injury manifestations. Patients with pre-existing cerebrovascular disease are at a higher risk of admission to the intensive care unit (ICU) and mortality. The neurological manifestations associated with COVID-19 are of great importance, but when life-threatening abnormal vital signs occur in severely ill COVID-19 patients, neurological problems are usually not considered. It is crucial to search for new treatments for brain damage, as well as for alternative therapies that recover the damaged brain and reduce the inflammatory response and its consequences for other organs. In addition, there is a need to diagnose these manifestations as early as possible to limit long-term consequences. Therefore, much research is needed to explain the involvement of SARS-CoV-2 causing these neurological symptoms because scientists know zero about it.
ABSTRACT
La enfermedad por coronavirus 2019 (CoViD-19) está causada por el virus del síndrome respiratorio agudo severo por coronavirus 2 (SARS-CoV-2), siendo particularmente perjudicial para los pacientes con enfermedad cardiovascular subyacente, y provocando una causa de morbilidad y mortalidad significativas en todo el mundo. Este virus lleva a una neumopatía, al tiempo que causa lesiones agudas de miocardio y daño crónico al sistema cardiovascular. Como consecuencia del daño del parénquima pulmonar y de la circulación pulmonar alterada, puede desarrollarse hipertensión pulmonar (HP), con su respectiva consecuencia. La fisiopatología de este tipo de HP es compleja y multifactorial, considerándose factores potenciales para las alteraciones de la circulación pulmonar. En estudios recientes, la prevalencia evidenciada de HP en pacientes con CoViD-19 es de alrededor del 12%, pero su evolución aún no está clara. La pandemia de CoViD-19 ha tenido un impacto significativo en todos los aspectos de la HP, desde el diagnóstico y manejo hasta la observación de un mayor riesgo de muerte en pacientes con hipertensión arterial pulmonar (HAP). En una encuesta de 77 centros de atención médica integral de HAP, la incidencia de infección por CoViD-19 fue de 2,1 casos por cada 1000 pacientes con HAP, similar a la incidencia de infección por CoViD-19 en la población general. Si bien, esta pandemia ha alterado el estándar de atención médica de rutina y de manejo agudo, particularmente, en aquellos pacientes con HAP, los riesgos asociados con CoViD-19 son significativos, presentándose nuevos desafíos en el cuidado de pacientes con HP. Dado que los pacientes con HAP han demostrado tener peores resultados en el ámbito de esta pandemia, es esencial trabajar de manera proactiva para disminuir el riesgo de infección por CoViD-19, mientras se continúa brindando un alto nivel de atención médica. El impacto de CoViD-19 en la prestación de atención médica y en la sociedad en general requirió que se establecieran nuevos protocolos para el tratamiento de HAP para disminuir el riesgo de exposición o transmisión de CoViD-19. De manera similar, ha habido una disminución en las pruebas de pacientes estables. Actualmente, la forma en que brindamos la atención médica se evidencia en un aumento de las visitas de telemedicina, una menor exposición a los entornos de atención médica para los pacientes y los profesionales de la salud, ayudando a nuestra necesidad continua de brindar servicios a los pacientes dentro del entorno de CoViD-19 y adaptándonos a una forma diferente de interactuar, ampliando nuestra comprensión de la mejor manera de cuidar a nuestros pacientes.
Coronavirus disease 2019 (CoViD-19) causes severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), being particularly harmful for patients with underlying cardiovascular disease, and causing a cause of significant morbidity and mortality throughout the world. This virus leads to lung disease, while causing acute myocardial injury and chronic damage to the cardiovascular system. As a consequence of the damage to the lung parenchyma and altered pulmonary circulation, pulmonary hypertension (PH) can develop, with its respective consequence. The pathophysiology of this type of PH is complex and multifactorial, considering potential factors for alterations in pulmonary circulation. In recent studies, the evidenced prevalence of PH in patients with CoViD-19 is around 12%, but its evolution is not yet clear. The CoViD-19 pandemic has had a significant impact on all aspects of PH, from diagnosis and management to observing an increased risk of death in patients with pulmonary arterial hypertension (PAH). In a survey of 77 comprehensive PAH healthcare centers, the incidence of CoViD-19 infection was 2.1 cases per 1,000 PAH patients, similar to the incidence of CoViD-19 infection in the general population. Although this pandemic has altered the standard of routine medical care and acute management, particularly in those patients with PAH, the risks associated with CoViD-19 are significant, presenting new challenges in the care of patients with PH. Since PAH patients have been shown to have worse outcomes in the setting of this pandemic, it is essential to work proactively to decrease the risk of CoViD-19 infection, while continuing to provide a high level of medical care. The impact of CoViD-19 on the provision of health care and on society in general required that new protocols be established for the treatment of PAH to reduce the risk of exposure or transmission of CoViD-19. Similarly, there has been a decline in stable patient testing. Currently, the way we provide healthcare is evidenced by an increase in telemedicine visits, less exposure to healthcare settings for patients and healthcare professionals, aiding our continued need to provide services to patients. patients within the CoViD-19 environment and adapting to a different way of interacting, broadening our understanding of the best way to care for our patients
A doença coronavírus 2019 (CoViD-19) causa síndrome respiratória aguda grave coronavírus 2 (SARS-CoV-2), sendo particularmente prejudicial para pacientes com doença cardiovascular subjacente e causando uma importante morbidade e mortalidade em todo o mundo. Este vírus leva à doença pulmonar, enquanto causa lesão aguda do miocárdio e dano crônico ao sistema cardiovascular. Como consequência do dano ao parênquima pulmonar e da circulação pulmonar alterada, pode ocorrer hipertensão pulmonar (HP), com suas respectivas consequências. A fisiopatologia desse tipo de HP é complexa e multifatorial, considerando fatores potenciais para alterações da circulação pulmonar. Em estudos recentes, a prevalência de HP evidenciada em pacientes com CoViD-19 gira em torno de 12%, mas sua evolução ainda não está clara. A pandemia CoViD-19 teve um impacto significativo em todos os aspectos da HP, desde o diagnóstico e tratamento até a observação de um risco aumentado de morte em pacientes com hipertensão arterial pulmonar (HAP). Em uma pesquisa com 77 centros de saúde com HAP abrangentes, a incidência de infecção por CoViD-19 foi de 2,1 casos por 1.000 pacientes com HAP, semelhante à incidência de infecção por CoViD-19 na população em geral. Embora essa pandemia tenha alterado o padrão de cuidados médicos de rotina e tratamento agudo, particularmente em pacientes com HAP, os riscos associados ao CoViD-19 são significativos, apresentando novos desafios no cuidado de pacientes com HP. Como os pacientes com HAP demonstraram ter resultados piores no cenário dessa pandemia, é essencial trabalhar proativamente para diminuir o risco de infecção por CoViD-19, enquanto continua a fornecer um alto nível de cuidados médicos. O impacto do CoViD-19 na prestação de cuidados de saúde e na sociedade em geral exigiu o estabelecimento de novos protocolos para o tratamento da HAP para reduzir o risco de exposição ou transmissão do CoViD-19. Da mesma forma, houve um declínio nos testes de pacientes estáveis. Atualmente, a forma como prestamos serviços de saúde é evidenciada por um aumento nas visitas de telemedicina, menos exposição aos ambientes de saúde para pacientes e profissionais de saúde, auxiliando nossa necessidade contínua de fornecer serviços aos pacientes. Pacientes dentro do ambiente CoViD-19 e adaptando-se de uma maneira diferente de interagir, ampliando nosso entendimento sobre a melhor forma de cuidar de nossos pacientes.
ABSTRACT
Angiotensin-Converting Enzyme 2 (ACE2) is an 805 amino acid protein encoded by the ACE2 gene expressed in various human cells, especially in those located in the epithelia. The primary function of ACE2 is to produce angiotensin (1-7) from angiotensin II (Ang II). The current research has described the importance of ACE2 and Ang (1-7) in alternative routes of the renin-angiotensin system (RAS) that promote the downregulation of fibrosis, inflammation, and oxidative stress processes in a great variety of diseases, such as hypertension, acute lung injury, liver cirrhosis, and kidney abnormalities. Investigations into the recent outbreak of the new severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) have revealed the importance of ACE2 during infection and its role in recognizing viral binding proteins through interactions with specific amino acids of this enzyme. Additionally, the ACE2 expression in several organs has allowed us to understand the clinical picture related to the infection caused by SARS-CoV-2. This review aims to provide context for the functions and importance of ACE2 with regards to SARS-CoV-2 in the general clinical aspect and its impact on other diseases, especially respiratory diseases.
ABSTRACT
La infección por SARS-CoV-2 (severe acute respiratory syndrome coronavirus 2) puede presentar manifestaciones propias, pero también, puede exacerbar las de enfermedades preexistentes o provocar manifestaciones que simulen dichas patologías. Las enfermedades cardiovasculares, neoplásicas o reumatológicas son ejemplos de ello. Este tipo de patologías comparten factores de riesgo de mal pronóstico y de muerte por la infección, la posibilidad de desarrollar complicaciones a largo plazo, e implican un desafío al momento de instaurar medidas de seguimiento y tratamiento con requerimiento de valoración multidisciplinaria. Por ello, nuestro objetivo fue plantear las dificultades en el seguimiento a corto y largo plazo de este tipo de pacientes y evaluar cómo la pandemia afecta su tratamiento. La pandemia ha cambiado la práctica médica habitual, promoviendo nuevas formas de seguimiento de los pacientes, como la telemedicina, imponiendo jerarquizar la necesidad de atención y procedimientos presenciales, obligando a reasignar las partidas presupuestarias para poder hacer frente a la misma, con consecuencias que probablemente habrá que analizar a largo plazo.
SARS-CoV-2 (severe acute respiratory syndrome coronavirus 2) infection clinical course can present its own manifestations, but it can also exacerbate those of pre-existing diseases or cause manifestations that simulate said pathologies. Cardiovascular, cancer or rheumatological diseases are examples of this. These types of pathologies share risk factors for poor prognosis and death due to infection, the possibility of developing long-term complications, and they imply a challenge when establishing follow-up and treatment measures requiring multidisciplinary assessment. Therefore, our objective was to raise the difficulties in the short and long-term follow-up of this type of patients and to evaluate how the pandemic affects their treatment. The pandemic has changed the usual medical practice, promoting new forms of patient follow-up, such as telemedicine, imposing a hierarchy of the need for face-to-face care and procedures, forcing budget items to be reallocated to be able to deal with it, with consequences that are likely to it will have to be analyzed in the long term.
A infecção por SARS-CoV-2 (severe acute respiratory syndrome coronavirus 2) pode apresentar manifestações próprias, mas também pode exacerbar aquelas de doenças pré-existentes ou causar manifestações que simulam essas patologias. Doenças cardiovasculares, neoplásicas ou reumatológicas são exemplos disso. Esses tipos de patologias compartilham fatores de risco para mau prognóstico e óbito por infecção, possibilidade de desenvolvimento de complicações em longo prazo, e representam um desafio no estabelecimento de medidas de acompanhamento e tratamento que requerem avaliação multidisciplinar. Portanto, nosso objetivo foi levantar as dificuldades no acompanhamento a curto e longo prazo desse tipo de paciente e avaliar como a pandemia afeta seu tratamento. A pandemia alterou a prática médica usual, promovendo novas formas de acompanhamento do paciente, como a telemedicina, impondo uma hierarquia da necessidade de atendimento e procedimentos presenciais, obrigando a realocação de itens orçamentários para poderem lidar com ela, com consequências que provavelmente terá que ser analisado a longo prazo.
ABSTRACT
BACKGROUND: The importance of dietary potassium in health and disease has been underestimated compared with that placed on dietary sodium. Larger effort has been made on reduction of sodium intake and less on the adequate dietary potassium intake, although natural food contains much more potassium than sodium. The benefits of a potassium-rich diet are known, however, the mechanism by which it exerts its preventive action, remains to be elucidated. With the hypothesis that dietary potassium reduces renal vasoconstrictor components of the renin-angiotensin system in the long-term, we studied the effect of high potassium diet on angiotensin-I converting enzyme, renin, and angiotensin converting enzyme 2. METHODS: Sprague Dawley male rats on a normal sodium diet received normal potassium (0.9%, NK) or high potassium diet (3%, HK) for 4 weeks. Urine was collected in metabolic cages for electrolytes and urinary volume measurement. Renal tissue was used to analyze angiotensin-I converting enzyme, renin, and angiotensin converting enzyme 2 expression. Protein abundance analysis was done by Western blot; gene expression by mRNA levels by RT-qPCR. Renal distribution of angiotensin-I converting enzyme and renin was done by immunohistochemistry and morphometric analysis in coded samples. RESULTS: High potassium diet (4 weeks) reduced the levels of renin, angiotensin-I converting enzyme, and angiotensin converting enzyme 2. Angiotensin-I converting enzyme was located in the brush border of proximal tubules and with HK diet decreased the immunostaining intensity (P < 0.05), decreased the mRNA (P < 0.01) and the protein levels (P < 0.01). Renin localization was restricted to granular cells of the afferent arteriole and HK diet decreased the number of renin positive cells (P < 0.01) and renin mRNA levels (P < 0.01). High potassium intake decreased angiotensin converting enzyme 2 gene expression and protein levels (P < 0.01).No morphological abnormalities were observed in renal tissue during high potassium diet.The reduced expression of angiotensin-I converting enzyme, renin, and angiotensin converting enzyme 2 during potassium supplementation suggest that high dietary potassium intake could modulate these vasoactive enzymes and this effects can contribute to the preventive and antihypertensive effect of potassium.
ABSTRACT
La enfermedad por coronavirus 2019 (COVID-19) provoca el síndrome respiratorio agudo severo por coronavirus 2 (SARS-CoV-2), pudiendo ser particularmente perjudicial para los pacientes con enfermedad cardiovascular (ECV) subyacente, y siendo una causa de morbilidad y mortalidad significativas en todo el mundo. El virus infecta las células huésped a través de los receptores de la enzima convertidora de la angiotensina 2 (ECA2) y su internalización del complejo en dicha célula. ACE2 es un componente enzimático clave del sistema renina-angiotensina-aldosterona (SRAA), degradando angiotensina (Ang) II, un péptido con múltiples acciones que promueven ECV, y generando Ang-(1-7), que antagoniza los efectos de Ang II. Además, la evidencia experimental sugiere que el bloqueo de SRAA por los inhibidores de la ECA y los antagonistas de los receptores de tipo 1 de Ang II, aumentan la ECA2 que, en parte, contribuye al beneficio de estos pacientes. Este virus lleva a una neumopatía, al tiempo que causa lesiones agudas de miocardio y daño crónico al sistema cardiovascular. Esta lesión miocárdica se presenta en la fase más severa de COVID-19; pero aún, el mecanismo fisiopatológico de la lesión no fue esclarecido. Por lo tanto, se debe prestar especial atención a la protección cardiovascular durante el tratamiento para COVID-19. El síndrome de dificultad respiratoria aguda (SDRA) es una enfermedad clínica de alta mortalidad, y ACE2 tiene un efecto protector sobre este tipo de lesión pulmonar aguda. La investigación actual muestra que el mal pronóstico de los pacientes con COVID-19 está relacionado con factores como género masculino, la edad >60 años, las enfermedades subyacentes: hipertensión, diabetes, ECV, SDRA secundario y otros factores relevantes. Si bien los datos son limitados, los posibles mecanismos de lesión miocárdica incluyen la entrada viral directa a través del receptor de membrana de la ECA2 y la toxicidad en las células huésped, la lesión de miocitos relacionada con la hipoxia y el síndrome de liberación de citoquinas mediado por el sistema inmune, necesitándose más estudios para esclarecer el mecanismo de cardiotoxicidad y su prevención. En este artículo se actualiza el conocimiento actual de la biología del SARS-CoV-2 y los posibles mecanismos de lesión miocárdica debido a toxicidades virales y respuestas inmunes del huésped.
Coronavirus disease 2019 (COVID-19) causes severe acute respiratory syndrome due to coronavirus 2 (SARS-CoV-2), and can be particularly detrimental to patients with underlying cardiovascular disease (CVD), and is a cause of morbidity and mortality. significant worldwide. The virus infects host cells through angiotensin-converting enzyme 2 (ACE2) receptors and their internalization of the complex into that cell. ACE2 is a key enzyme component of the renin-angiotensin-aldosterone (RAAS) system, degrading angiotensin (Ang) II, a peptide with multiple actions that promote CVD, and generating Ang- (1-7), which antagonizes the effects of Ang II . Furthermore, experimental evidence suggests that blocking SRAA by ACE inhibitors and Ang II type 1 receptor antagonists increases ACE2, which in part contributes to the benefit of these patients. This virus leads to lung disease, while causing acute myocardial injury and chronic damage to the cardiovascular system. This myocardial injury occurs in the most severe phase of COVID-19; but still, the pathophysiological mechanism of the injury was not clarified. Therefore, special attention should be paid to cardiovascular protection during treatment for COVID-19. Acute respiratory distress syndrome (ARDS) is a highmortality clinical disease, and ACE2 has a protective effect on this type of acute lung injury. Current research shows that the poor prognosis of COVID-19 patients is related to factors such as male gender, age> 60 years, underlying diseases: hypertension, diabetes and CVD, secondary ARDS, and other relevant factors. Although the data is limited, possible mechanisms of myocardial injury include direct viral entry through the ACE2 membrane receptor and host cell toxicity, hypoxia-related myocyte injury, and cytokine release syndrome. mediated by the immune system, further studies are needed to clarify the mechanism of cardiotoxicity and its prevention. This article updates current knowledge of the biology of SARS-CoV-2 and the possible mechanisms of myocardial injury due to viral toxicities and host immune responses.
A doença de coronavírus 2019 (COVID-19) causa síndrome respiratória aguda grave devido ao coronavírus 2 (SARSCoV-2) e pode ser particularmente prejudicial para pacientes com doença cardiovascular subjacente (DCV) e é uma causa de morbidade e mortalidade significativo em todo o mundo. O vírus infecta as células hospedeiras através dos receptores da enzima conversora de angiotensina 2 (ECA2) e sua internalização do complexo nessa célula. O ACE2 é um componente enzimático chave do sistema renina-angiotensina-aldosterona (SRAA), degradando a angiotensina (Ang) II, um peptídeo com múltiplas ações que promovem DCV e gerando Ang- (1-7), que antagoniza os efeitos da Ang II . Além disso, evidências experimentais sugerem que o bloqueio do SRAA por inibidores da ECA e antagonistas dos receptores Ang II tipo 1 aumenta a ECA2, o que em parte contribui para o benefício desses pacientes. Este vírus leva a doenças pulmonares, causando lesão miocárdica aguda e danos crônicos ao sistema cardiovascular. Essa lesão do miocárdio ocorre na fase mais grave do COVID-19; mas ainda assim, o mecanismo fisiopatológico da lesão não foi esclarecido. Portanto, atenção especial deve ser dada à proteção cardiovascular durante o tratamento para COVID-19. A síndrome do desconforto respiratório agudo (SDRA) é uma doença clínica de alta mortalidade e a ECA2 tem um efeito protetor sobre esse tipo de lesão pulmonar aguda. Pesquisas atuais mostram que o mau prognóstico dos pacientes com COVID-19 está relacionado a fatores como sexo masculino, idade> 60 anos, doenças subjacentes: hipertensão, diabetes e DCV, SDRA secundária e outros fatores relevantes. Embora os dados sejam limitados, os possíveis mecanismos de lesão do miocárdio incluem entrada viral direta através do receptor da membrana ACE2 e toxicidade das células hospedeiras, lesão de miócitos relacionados à hipóxia e síndrome de liberação de citocinas.mediados pelo sistema imunológico, são necessários mais estudos para esclarecer o mecanismo da cardiotoxicidade e sua prevenção. Este artigo atualiza o conhecimento atual da biologia da SARS-CoV-2 e os possíveis mecanismos de lesão do miocárdio devido a toxicidades virais e respostas imunes do hospedeiro.
ABSTRACT
Nowadays the adipose tissue is recognized as one of the most critical endocrine organs releasing many adipokines that regulate metabolism, inflammation and body homeostasis. There are several described adipokines, including the renin-angiotensin system (RAS) components that are especially activated in some diseases with increased production of angiotensin II and several pro-inflammatory hormones. On the other hand, RAS also expresses angiotensin-(1-7), which is now recognized as the main peptide on counteracting Ang II effects. New studies have shown that increased activation of ACE2/Ang-(1-7)/MasR arm can revert and prevent local and systemic dysfunctions improving lipid profile and insulin resistance by modulating insulin actions, and reducing inflammation. In this context, the present review shows the interaction and relevance of Ang-(1-7) effects on regulating adipokines, and as one adipokine itself, modulating body homeostasis, with emphasis on its anti-inflammatory properties, especially in the context of metabolic disorders with focus on obesity and type 2 diabetes mellitus pandemic.
Subject(s)
Adipokines/metabolism , Angiotensin I/metabolism , Inflammation/metabolism , Peptide Fragments/metabolism , Adipose Tissue/metabolism , Animals , Humans , Proto-Oncogene MasABSTRACT
The renin-angiotensin system (RAS) regulates skeletal muscle insulin sensitivity through different mechanisms. The overactivation of the ACE (angiotensin-converting enzyme)/Ang (angiotensin) II/AT1R (Ang II type 1 receptor) axis has been associated with the development of insulin resistance, whereas the stimulation of the ACE2/Ang 1-7/MasR (Mas receptor) axis improves insulin sensitivity. The in vivo mechanisms by which this axis enhances skeletal muscle insulin sensitivity are scarcely known. In this work, we investigated whether rat soleus muscle expresses the ACE2/Ang 1-7/MasR axis and determined the effect of Ang 1-7 on rat skeletal muscle glucose uptake in vivo. Western blot analysis revealed the expression of ACE2 and MasR, while Ang 1-7 levels were detected in rat soleus muscle by capillary zone electrophoresis. The euglycemic clamp exhibited that Ang 1-7 by itself did not promote glucose transport, but it increased insulin-stimulated glucose disposal in the rat. In a similar manner, captopril (an ACE inhibitor) enhanced insulin-induced glucose uptake and this effect was blocked by the MasR antagonist A-779. Our results show for the first time that rat soleus muscle expresses the ACE2/Ang 1-7/MasR axis of the RAS, and Ang 1-7 improves insulin sensitivity by enhancing insulin-stimulated glucose uptake in rat skeletal muscle in vivo. Thus, endogenous (systemic and/or local) Ang 1-7 could regulate insulin-mediated glucose transport in vivo.