FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4378978412> ?p ?o ?g. }

• W4378978412 endingPage "656" @default.
• W4378978412 startingPage "645" @default.
• W4378978412 abstract "Any acute and profound reduction in fetal oxygenation increases the risk of anaerobic metabolism in the fetal myocardium and, hence, the risk of lactic acidosis. On the contrary, in a gradually evolving hypoxic stress, there is sufficient time to mount a catecholamine-mediated increase in the fetal heart rate to increase the cardiac output and redistribute oxygenated blood to maintain an aerobic metabolism in the fetal central organs. When the hypoxic stress is sudden, profound, and sustained, it is not possible to continue to maintain central organ perfusion by peripheral vasoconstriction and centralization. In case of acute deprivation of oxygen, the immediate chemoreflex response via the vagus nerve helps reduce fetal myocardial workload by a sudden drop of the baseline fetal heart rate. If this drop in the fetal heart rate continues for >2 minutes (American College of Obstetricians and Gynecologists’ guideline) or 3 minutes (National Institute for Health and Care Excellence or physiological guideline), it is termed a prolonged deceleration, which occurs because of myocardial hypoxia, after the initial chemoreflex. The revised International Federation of Gynecology and Obstetrics guideline (2015) considers the prolonged deceleration to be a “pathologic” feature after 5 minutes. Acute intrapartum accidents (placental abruption, umbilical cord prolapse, and uterine rupture) should be excluded immediately, and if they are present, an urgent birth should be accomplished. If a reversible cause is found (maternal hypotension, uterine hypertonus or hyperstimulation, and sustained umbilical cord compression), immediate conservative measures (also called intrauterine fetal resuscitation) should be undertaken to reverse the underlying cause. In reversible causes of acute hypoxia, if the fetal heart rate variability is normal before the onset of deceleration, and normal within the first 3 minutes of the prolonged deceleration, then there is an increased likelihood of recovery of the fetal heart rate to its antecedent baseline within 9 minutes with the reversal of the underlying cause of acute and profound reduction in fetal oxygenation. The continuation of the prolonged deceleration for >10 minutes is termed “terminal bradycardia,” and this increases the risk of hypoxic-ischemic injury to the deep gray matter of the brain (the thalami and the basal ganglia), predisposing to dyskinetic cerebral palsy. Therefore, any acute fetal hypoxia, which manifests as a prolonged deceleration on the fetal heart rate tracing, should be considered an intrapartum emergency requiring an immediate intervention to optimize perinatal outcome. In uterine hypertonus or hyperstimulation, if the prolonged deceleration persists despite stopping the uterotonic agent, then acute tocolysis is recommended to rapidly restore fetal oxygenation. Regular clinical audit of the management of acute hypoxia, including the “the onset of bradycardia to delivery interval,” may help identify organizational and system issues, which may contribute to poor perinatal outcomes. Any acute and profound reduction in fetal oxygenation increases the risk of anaerobic metabolism in the fetal myocardium and, hence, the risk of lactic acidosis. On the contrary, in a gradually evolving hypoxic stress, there is sufficient time to mount a catecholamine-mediated increase in the fetal heart rate to increase the cardiac output and redistribute oxygenated blood to maintain an aerobic metabolism in the fetal central organs. When the hypoxic stress is sudden, profound, and sustained, it is not possible to continue to maintain central organ perfusion by peripheral vasoconstriction and centralization. In case of acute deprivation of oxygen, the immediate chemoreflex response via the vagus nerve helps reduce fetal myocardial workload by a sudden drop of the baseline fetal heart rate. If this drop in the fetal heart rate continues for >2 minutes (American College of Obstetricians and Gynecologists’ guideline) or 3 minutes (National Institute for Health and Care Excellence or physiological guideline), it is termed a prolonged deceleration, which occurs because of myocardial hypoxia, after the initial chemoreflex. The revised International Federation of Gynecology and Obstetrics guideline (2015) considers the prolonged deceleration to be a “pathologic” feature after 5 minutes. Acute intrapartum accidents (placental abruption, umbilical cord prolapse, and uterine rupture) should be excluded immediately, and if they are present, an urgent birth should be accomplished. If a reversible cause is found (maternal hypotension, uterine hypertonus or hyperstimulation, and sustained umbilical cord compression), immediate conservative measures (also called intrauterine fetal resuscitation) should be undertaken to reverse the underlying cause. In reversible causes of acute hypoxia, if the fetal heart rate variability is normal before the onset of deceleration, and normal within the first 3 minutes of the prolonged deceleration, then there is an increased likelihood of recovery of the fetal heart rate to its antecedent baseline within 9 minutes with the reversal of the underlying cause of acute and profound reduction in fetal oxygenation. The continuation of the prolonged deceleration for >10 minutes is termed “terminal bradycardia,” and this increases the risk of hypoxic-ischemic injury to the deep gray matter of the brain (the thalami and the basal ganglia), predisposing to dyskinetic cerebral palsy. Therefore, any acute fetal hypoxia, which manifests as a prolonged deceleration on the fetal heart rate tracing, should be considered an intrapartum emergency requiring an immediate intervention to optimize perinatal outcome. In uterine hypertonus or hyperstimulation, if the prolonged deceleration persists despite stopping the uterotonic agent, then acute tocolysis is recommended to rapidly restore fetal oxygenation. Regular clinical audit of the management of acute hypoxia, including the “the onset of bradycardia to delivery interval,” may help identify organizational and system issues, which may contribute to poor perinatal outcomes." @default.
• W4378978412 created "2023-06-02" @default.
• W4378978412 creator A5011259015 @default.
• W4378978412 creator A5045421067 @default.
• W4378978412 creator A5070878807 @default.
• W4378978412 creator A5077726920 @default.
• W4378978412 date "2023-06-01" @default.
• W4378978412 modified "2023-10-18" @default.
• W4378978412 title "Optimizing the management of acute, prolonged decelerations and fetal bradycardia based on the understanding of fetal pathophysiology" @default.
• W4378978412 cites W1488209620 @default.
• W4378978412 cites W1632941953 @default.
• W4378978412 cites W1875915783 @default.
• W4378978412 cites W1931727703 @default.
• W4378978412 cites W1972747747 @default.
• W4378978412 cites W1975929856 @default.
• W4378978412 cites W1990143242 @default.
• W4378978412 cites W1992125023 @default.
• W4378978412 cites W1995493857 @default.
• W4378978412 cites W1999147193 @default.
• W4378978412 cites W2009727936 @default.
• W4378978412 cites W2012122155 @default.
• W4378978412 cites W2014539044 @default.
• W4378978412 cites W2015260376 @default.
• W4378978412 cites W2020279210 @default.
• W4378978412 cites W2022644514 @default.
• W4378978412 cites W2024532727 @default.
• W4378978412 cites W2025991670 @default.
• W4378978412 cites W2029672442 @default.
• W4378978412 cites W2033070664 @default.
• W4378978412 cites W2042479607 @default.
• W4378978412 cites W2043216371 @default.
• W4378978412 cites W2056806643 @default.
• W4378978412 cites W2060320905 @default.
• W4378978412 cites W2076987751 @default.
• W4378978412 cites W2078693874 @default.
• W4378978412 cites W2079012288 @default.
• W4378978412 cites W2088252999 @default.
• W4378978412 cites W2098466981 @default.
• W4378978412 cites W2102585807 @default.
• W4378978412 cites W2136692475 @default.
• W4378978412 cites W2256321467 @default.
• W4378978412 cites W2527909784 @default.
• W4378978412 cites W2766272700 @default.
• W4378978412 cites W2790442026 @default.
• W4378978412 cites W2980961803 @default.
• W4378978412 cites W2990971305 @default.
• W4378978412 cites W3019828418 @default.
• W4378978412 cites W3081755918 @default.
• W4378978412 cites W3094110589 @default.
• W4378978412 cites W3110771087 @default.
• W4378978412 cites W3116062041 @default.
• W4378978412 cites W3201626977 @default.
• W4378978412 cites W4233846751 @default.
• W4378978412 cites W4238453858 @default.
• W4378978412 cites W4253660560 @default.
• W4378978412 cites W798407487 @default.
• W4378978412 doi "https://doi.org/10.1016/j.ajog.2022.05.014" @default.
• W4378978412 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/37270260" @default.
• W4378978412 hasPublicationYear "2023" @default.
• W4378978412 type Work @default.
• W4378978412 citedByCount "0" @default.
• W4378978412 crossrefType "journal-article" @default.
• W4378978412 hasAuthorship W4378978412A5011259015 @default.
• W4378978412 hasAuthorship W4378978412A5045421067 @default.
• W4378978412 hasAuthorship W4378978412A5070878807 @default.
• W4378978412 hasAuthorship W4378978412A5077726920 @default.
• W4378978412 hasConcept C105702510 @default.
• W4378978412 hasConcept C126322002 @default.
• W4378978412 hasConcept C164705383 @default.
• W4378978412 hasConcept C172680121 @default.
• W4378978412 hasConcept C178790620 @default.
• W4378978412 hasConcept C185592680 @default.
• W4378978412 hasConcept C2776955114 @default.
• W4378978412 hasConcept C2777495988 @default.
• W4378978412 hasConcept C2777953023 @default.
• W4378978412 hasConcept C2779234561 @default.
• W4378978412 hasConcept C42219234 @default.
• W4378978412 hasConcept C540031477 @default.
• W4378978412 hasConcept C54355233 @default.
• W4378978412 hasConcept C71924100 @default.
• W4378978412 hasConcept C7836513 @default.
• W4378978412 hasConcept C84393581 @default.
• W4378978412 hasConcept C86803240 @default.
• W4378978412 hasConceptScore W4378978412C105702510 @default.
• W4378978412 hasConceptScore W4378978412C126322002 @default.
• W4378978412 hasConceptScore W4378978412C164705383 @default.
• W4378978412 hasConceptScore W4378978412C172680121 @default.
• W4378978412 hasConceptScore W4378978412C178790620 @default.
• W4378978412 hasConceptScore W4378978412C185592680 @default.
• W4378978412 hasConceptScore W4378978412C2776955114 @default.
• W4378978412 hasConceptScore W4378978412C2777495988 @default.
• W4378978412 hasConceptScore W4378978412C2777953023 @default.
• W4378978412 hasConceptScore W4378978412C2779234561 @default.
• W4378978412 hasConceptScore W4378978412C42219234 @default.
• W4378978412 hasConceptScore W4378978412C540031477 @default.
• W4378978412 hasConceptScore W4378978412C54355233 @default.
• W4378978412 hasConceptScore W4378978412C71924100 @default.
• W4378978412 hasConceptScore W4378978412C7836513 @default.

• next