The Central Effects of Thyrotropin-Releasing Hormone on the Breathing Movements and Electrocortical Activity of the Fetal Sheep

Gluckman, Peter D.; Johnston, Barbara M.

doi:10.1203/00006450-198801000-00016

Cited by 18 publications

(14 citation statements)

References 22 publications

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“…Regarding the mechanism of action, TRH targets G ␣q -protein-linked receptors that may directly block twopore-domain K ϩ channels (Chen et al, 2006;Töpert et al, 1998) that are proposed to contribute to respiratory rhythm generation (Ballanyi et al, 1999;Smith et al, 2000). While the respiratory stimulatory action of TRH is established (Hedner et al, 1983; Bennet et al, 1988), we report for the first time that DHPG-mediated activation of metabotropic glutamate receptors induces PBC rhythm. Locomotor networks in neonatal rats (Nistri et al, 2006) and respiratory networks in lampreys (Bongianni et al, 2002) are similarly sensitive to the agent.…”

Section: Calibrated Pbc Slicesmentioning

confidence: 83%

High Sensitivity to Neuromodulator-Activated Signaling Pathways at Physiological [K⁺] of Confocally Imaged Respiratory Center Neurons in On-Line-Calibrated Newborn Rat Brainstem Slices

Ruangkittisakul¹,

Schwarzacher²,

Secchia³

et al. 2006

J. Neurosci.

136

153

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The pre-Bötzinger complex (PBC) inspiratory center remains active in a transverse brainstem slice. Such slices are studied at high (8 -10 mM) superfusate [K ϩ ], which could attenuate the sensitivity of the PBC to neuromodulators such as opiates. Findings may also be confounded because slice boundaries, drug injection sites, or location of rhythmogenic interneurons are rarely verified histologically. Thus, we first generated PBC slices with defined boundaries using novel "on-line histology" based on our finding that rostrocaudal extensions of brainstem respiratory marker nuclei are constant in newborn rats between postnatal days 0 -4. At physiological superfusate ] generate rhythm with a high sensitivity to neuromodulators for extended time periods, whereas spontaneous "in vitro apnea" is an important tool to study the interaction of signaling pathways that modulate rhythm. Our approaches and findings provide the basis for a pharmacological and structure-function analysis of the isolated respiratory center in a histologically well defined substrate at physiological [K ϩ ].

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Section: Calibrated Pbc Slicesmentioning

confidence: 83%

High Sensitivity to Neuromodulator-Activated Signaling Pathways at Physiological [K⁺] of Confocally Imaged Respiratory Center Neurons in On-Line-Calibrated Newborn Rat Brainstem Slices

Ruangkittisakul¹,

Schwarzacher²,

Secchia³

et al. 2006

J. Neurosci.

136

153

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“…However, those observations were made 45 min from the start (15 min from the end) of TRH infusion, and changes persisted in some fetuses for up to 8 h. Although the exact pharmacokinetics and dynamics of TRH remain to be determined, it seems unlikely, given the extremely short half-life of TRH, that these effects were the direct result of a rise in fetal TRH levels. Notwithstanding this, sheep studies indicate that TRH-induced FBM changes persist for at least 15 min after intravenous injection to the fetus, and for 25-43 min after intracisternal injection in the fetus [8,9].…”

Section: Discussionmentioning

confidence: 99%

Effects of Antenatal Thyrotropin-Releasing Hormone on Fetal Heart Rate and Breathing Movements

Peek

Bajoria²,

Talbert³

et al. 1998

Fetal Diagn Ther

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Objective: To determine the effect of maternally administered thyrotropin-releasing hormone (TRH) on fetal heart rate (FHR) pattern and fetal breathing movements (FBM). Methods: Prospective observational study of 75 pregnant women between 26 and 34 weeks’ gestation in whom pharmacological fetal lung maturation was clinically indicated. Forty-minute recordings were made of FBM or FHR patterns before and after drug administration. Twenty-five received TRH 400 µg as an intravenous bolus, 25 TRH 400 µg in 50 ml 0.9% saline as an intraveous infusion, and 25 acted as controls. Recordings were processed digitally to calculate the change in FHR (n = 45) and FBM parameters (n = 30). The main outcome measures for FHR were number of accelerations and decelerations, baseline rate, overall and short-term variation and duration of high and low variability, while for FBM they were rate, breath-to-breath interval and incidence. Results between groups were compared by analysis of variance. Results: There was no significant change in FHR, accelerations or variation in any of the groups. Similarly, there was no change in the incidence of FBM. TRH administered as a bolus produced a small statistically but not clinically significant increase in breathing rate (mean Δ = 35 breaths/h, p = 0.004), which was not seen in the TRH infusion and control groups. Conclusions: Maternally administered TRH as used to enhance fetal lung maturation has no clinically significant direct effect on FHR or FBM patterns.

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“…Shivering in young guinea-pigs is determined by the temperature gradient between the cervical vertebral canal and skin, rather than hypothalamic temperature [14]. It is not known if a similar situation occurs in the newborn lamb, although TRH administration into the lateral cerebral ventricles of fetal lambs stimulates breathing [8], an adaptation that can be accompanied by shivering following skin surface cooling [15]. A response of this type could explain why in the current study TRH administration to caesarean section delivered lambs stimulated both shivering and ventilation.…”

Section: Discussionmentioning

confidence: 99%

“…Thyrotrophin-releasing hormone (TRH) content in the hypothalamus peaks close to term [7] and an increase in the rate of TRH secretion during parturition has been proposed to provide an important stimulus necessary for the establishment of continuous breathing after birth [8]. A delay or reduced rate of TRH release following birth by caesarean section due to the absence of physical stress associated with vaginal delivery could be a primary factor contributing to low plasma thyroid hormone concentrations in caesarean section delivered lambs [3].…”

Section: Introductionmentioning

confidence: 99%

Influence of Thyrotrophin-Releasing Hormone on Thermoregulation in Newborn Lambs

Bird

Clarke²,

Symonds³

1997

Neonatology

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This study examined the effect of thyrotrophin-releasing hormone (TRH) administration on thermoregulation in the newborn. Twin lambs were either delivered near-term by caesarean section or born vaginally at term. Colonic temperature, O₂ consumption, CO₂ production, breathing and heart rates, plus plasma thyroid hormone and nonesterified fatty acid (NEFA) concentrations and thermogenic activity (i.e. GDP binding) of brown adipose tissue (BAT) were measured. In caesarean section delivered lambs colonic temperature decreased rapidly after birth, a response that was greater in the group designated for TRH treatment, in which colonic temperature fell to below 36.0°C at 80 min of life, prior to TRH administration. At this age colonic temperature had been restored to a mean of 38.70°C in controls. TRH had no influence on the composition or thermogenic activity of BAT. The incidence of shivering was not influenced by TRH, but treated lambs maintained a higher rate of O₂ consumption and ventilation compared with controls after colonic temperature had been restored to 38.56°C. TRH appeared to promote fat oxidation as O₂ consumption remained unchanged and CO₂ production declined by a greater rate in treated lambs, resulting in a lower respiratory quotient compared to controls. Heart rate and plasma concentrations of NEFA increased following TRH administration although this did not result in values greater than controls. Normothermic lambs born vaginally had BAT with a greater thermogenic activity, higher plasma thyroid hormone and NEFA concentrations compared with caesarean section delivered lambs, but a thermogenic response was not observed to TRH despite a rise in thyroid hormone concentrations. In conclusion, TRH can improve thermoregulation, an effect that could be linked to an increase in fat oxidation.

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The Central Effects of Thyrotropin-Releasing Hormone on the Breathing Movements and Electrocortical Activity of the Fetal Sheep

Cited by 18 publications

References 22 publications

High Sensitivity to Neuromodulator-Activated Signaling Pathways at Physiological [K⁺] of Confocally Imaged Respiratory Center Neurons in On-Line-Calibrated Newborn Rat Brainstem Slices

High Sensitivity to Neuromodulator-Activated Signaling Pathways at Physiological [K⁺] of Confocally Imaged Respiratory Center Neurons in On-Line-Calibrated Newborn Rat Brainstem Slices

Effects of Antenatal Thyrotropin-Releasing Hormone on Fetal Heart Rate and Breathing Movements

Influence of Thyrotrophin-Releasing Hormone on Thermoregulation in Newborn Lambs

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The Central Effects of Thyrotropin-Releasing Hormone on the Breathing Movements and Electrocortical Activity of the Fetal Sheep

Cited by 18 publications

References 22 publications

High Sensitivity to Neuromodulator-Activated Signaling Pathways at Physiological [K+] of Confocally Imaged Respiratory Center Neurons in On-Line-Calibrated Newborn Rat Brainstem Slices

High Sensitivity to Neuromodulator-Activated Signaling Pathways at Physiological [K+] of Confocally Imaged Respiratory Center Neurons in On-Line-Calibrated Newborn Rat Brainstem Slices

Effects of Antenatal Thyrotropin-Releasing Hormone on Fetal Heart Rate and Breathing Movements

Influence of Thyrotrophin-Releasing Hormone on Thermoregulation in Newborn Lambs

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High Sensitivity to Neuromodulator-Activated Signaling Pathways at Physiological [K⁺] of Confocally Imaged Respiratory Center Neurons in On-Line-Calibrated Newborn Rat Brainstem Slices

High Sensitivity to Neuromodulator-Activated Signaling Pathways at Physiological [K⁺] of Confocally Imaged Respiratory Center Neurons in On-Line-Calibrated Newborn Rat Brainstem Slices