SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3001156532> ?p ?o ?g. }

Showing items 1 to 100 of ±117 with 100 items per page.

W3001156532 endingPage "109574" @default.
W3001156532 startingPage "109574" @default.
W3001156532 abstract "Autonomic Nervous System (ANS) operates to achieve the optimum physiological functioning and maintains homeostasis in a tonic and continuous manner. Evaluation of ANS profile is crucial in assessing autonomic dysfunction. Conventional ANS evaluation procedures fail to capture minute dynamic alterations of ANS activities. The ANS output pattern is appropriately reflected in the fine alteration of the resting heart rate (HR). HR is a non-stationary variable, results from the dynamic interplay between the multiple physiologic mechanisms. The control of cardiac rate or the chronotropic regulation of heart is considered as a coupled network of oscillators, each representing a specific facet of the cardiovascular reflex. The slower vasomotor oscillation via sympathetic system is combined with rapid respiratory oscillation by parasympathetic system to modulate the intrinsic oscillation pattern of the SA Node. Heart Rate Variability (HRV) is used to understand the autonomic influence on cardiovascular system in health and disease. Fourier decomposition of HRV offers us mainly two different frequency components. High frequency (HF) variation indicates parasympathetic variability due to respiration and Low frequency (LF) mainly implicates tonic sympathetic influence, due to slower vasomotor modulation of heart rate. However, different studies show conflicting results and direct recording of sympathetic nerve activity also failed to correlate with LF power in either healthy subjects or in patients with increased cardiac sympathetic drive. A scatter-plot where each R-R interval is plotted against the preceding R-R interval forms a distributed elliptic point cloud in two dimensional plane. The phase space realization of this plot with dimension two and delay one is referred to as Poincare plot analysis, an emerging quantitative-visual technique where the shape of the plot is categorized into different functional classes. The plot provides summary as well as detailed beat-to-beat information of the heart. This plot can be extended to three dimensions and with multi-lag, offering more insight and information. A mathematical expression was developed by an interventional study by Toichi et al., using pharmacological blockers during different physiological variables that calculated the lengths of transverse and longitudinal axes of the Poincare plot to derive two quantitative expressions of sympathetic and vagal influence on HRV: 'cardiac sympathetic index' (CSI)) and 'cardiac vagal index' (CVI). In the present study, we emulate Poincare plot patterns seen in normal range of sympatho-vagal balances and also in Diabetes Mellitus (DM), known to cause autonomic dysfunction. The emerging pattern of R-R interval time series would provide valuable insight into the altered temporal dynamics and also extract crucial features embedded within. DM is a major public health crisis globally and particularly in Indian population. We hypothesize that, CSI and CVI will effectively segregate the two arms of ANS and can be utilized as an effective evaluation tool to explore the disease status in patients of Diabetes Mellitus. We also propose that, the dynamics of fluctuations in physiological rhythms that exhibit long-term correlation and memory, can also be explored and expressed quantitatively by incorporating various degrees of 'lag' in these recurrence plots." @default.
W3001156532 created "2020-01-30" @default.
W3001156532 creator A5024566240 @default.
W3001156532 creator A5053591276 @default.
W3001156532 creator A5072349136 @default.
W3001156532 date "2020-05-01" @default.
W3001156532 modified "2023-09-27" @default.
W3001156532 title "Geometry of the Poincaré plot can segregate the two arms of autonomic nervous system – A hypothesis" @default.
W3001156532 cites W1531145115 @default.
W3001156532 cites W1549386224 @default.
W3001156532 cites W1783282123 @default.
W3001156532 cites W1975616941 @default.
W3001156532 cites W1976338337 @default.
W3001156532 cites W1985923799 @default.
W3001156532 cites W2011278787 @default.
W3001156532 cites W2026699230 @default.
W3001156532 cites W2028636860 @default.
W3001156532 cites W2033028174 @default.
W3001156532 cites W2042273803 @default.
W3001156532 cites W2045857500 @default.
W3001156532 cites W2048686658 @default.
W3001156532 cites W2048811598 @default.
W3001156532 cites W2057486798 @default.
W3001156532 cites W2068002517 @default.
W3001156532 cites W2070269016 @default.
W3001156532 cites W2071526303 @default.
W3001156532 cites W2076975832 @default.
W3001156532 cites W2089721029 @default.
W3001156532 cites W2107161633 @default.
W3001156532 cites W2112400936 @default.
W3001156532 cites W2113640125 @default.
W3001156532 cites W2116337118 @default.
W3001156532 cites W2117644546 @default.
W3001156532 cites W2118573445 @default.
W3001156532 cites W2124146263 @default.
W3001156532 cites W2127364835 @default.
W3001156532 cites W2128242332 @default.
W3001156532 cites W2138969187 @default.
W3001156532 cites W2139573429 @default.
W3001156532 cites W2148705602 @default.
W3001156532 cites W2150789152 @default.
W3001156532 cites W2156387998 @default.
W3001156532 cites W2163183941 @default.
W3001156532 cites W2183597852 @default.
W3001156532 cites W2399259105 @default.
W3001156532 cites W2478216181 @default.
W3001156532 cites W2520210802 @default.
W3001156532 cites W2534013721 @default.
W3001156532 cites W2591531894 @default.
W3001156532 cites W2759190050 @default.
W3001156532 cites W2791877089 @default.
W3001156532 cites W2921305858 @default.
W3001156532 cites W2936828451 @default.
W3001156532 cites W2947788357 @default.
W3001156532 cites W4205567043 @default.
W3001156532 cites W4234284487 @default.
W3001156532 cites W4244576960 @default.
W3001156532 cites W82976667 @default.
W3001156532 doi "https://doi.org/10.1016/j.mehy.2020.109574" @default.
W3001156532 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/32014816" @default.
W3001156532 hasPublicationYear "2020" @default.
W3001156532 type Work @default.
W3001156532 sameAs 3001156532 @default.
W3001156532 citedByCount "5" @default.
W3001156532 countsByYear W30011565322021 @default.
W3001156532 countsByYear W30011565322022 @default.
W3001156532 countsByYear W30011565322023 @default.
W3001156532 crossrefType "journal-article" @default.
W3001156532 hasAuthorship W3001156532A5024566240 @default.
W3001156532 hasAuthorship W3001156532A5053591276 @default.
W3001156532 hasAuthorship W3001156532A5072349136 @default.
W3001156532 hasConcept C105795698 @default.
W3001156532 hasConcept C121332964 @default.
W3001156532 hasConcept C134018914 @default.
W3001156532 hasConcept C134306372 @default.
W3001156532 hasConcept C167651023 @default.
W3001156532 hasConcept C169760540 @default.
W3001156532 hasConcept C2524010 @default.
W3001156532 hasConcept C2777372248 @default.
W3001156532 hasConcept C2777953023 @default.
W3001156532 hasConcept C33923547 @default.
W3001156532 hasConcept C84393581 @default.
W3001156532 hasConcept C86803240 @default.
W3001156532 hasConcept C88221313 @default.
W3001156532 hasConceptScore W3001156532C105795698 @default.
W3001156532 hasConceptScore W3001156532C121332964 @default.
W3001156532 hasConceptScore W3001156532C134018914 @default.
W3001156532 hasConceptScore W3001156532C134306372 @default.
W3001156532 hasConceptScore W3001156532C167651023 @default.
W3001156532 hasConceptScore W3001156532C169760540 @default.
W3001156532 hasConceptScore W3001156532C2524010 @default.
W3001156532 hasConceptScore W3001156532C2777372248 @default.
W3001156532 hasConceptScore W3001156532C2777953023 @default.
W3001156532 hasConceptScore W3001156532C33923547 @default.
W3001156532 hasConceptScore W3001156532C84393581 @default.
W3001156532 hasConceptScore W3001156532C86803240 @default.
W3001156532 hasConceptScore W3001156532C88221313 @default.
W3001156532 hasLocation W30011565321 @default.