Hypersensitive and Circadian Effects of Acebutolol Administration in Scn1b-/- Mice

Authors' Affiliations

William Thompson, Department of Biomedical Sciences, College of Public Health, East Tennessee State University, Johnson City, TN. Dr. Chad Frasier, Department of Biomedical Sciences, Quillen College of Medicine, East Tennessee State University, Johnson City, TN. Jessa Aldridge, Department of Biomedical Sciences, Quillen College of Medicine, East Tennessee State University, Johnson City, TN. Emily Alexander, Department of Biomedical Sciences, Quillen College of Medicine, East Tennessee State University, Johnson City, TN. Hazlee Kleine, Department of Biomedical Sciences, Quillen College of Medicine, East Tennessee State University, Johnson City, TN.

Location

Culp Center Ballroom

Start Date

4-25-2023 9:00 AM

End Date

4-25-2023 11:00 AM

Poster Number

131

Faculty Sponsor’s Department

Biomedical Sciences

Name of Project's Faculty Sponsor

Chad Frasier

Classification of First Author

Undergraduate Student

Competition Type

Non-Competitive

Type

Oral Presentation

Project's Category

Neurological Disorders

Abstract or Artist's Statement

Title: Hypersensitive and circadian effects of acebutolol administration in Scn1b-/- mice.

Rationale: Dravet syndrome (DS) is a severe form of pediatric epilepsy with characterizations of pharmacoresistant seizures and developmental delay. A rarer variant of the DS model is caused by homozygous loss-of-function mutations in SCN1B, which is essential in regulating sodium channel gating, expression, localization, and the firing of action potentials. Mutations in SCN1B result in severe seizures as well as a higher risk of Sudden Unexpected Death in EPilepsy (SUDEP). Factors underlying SUDEP are poorly understood, although cardiac arrhythmias have been implicated. Acebutolol (ACE) is a common beta-blocker used in the treatment of arrhythmias and hypertension. We hypothesized that treating mice with ACE will decrease cardiac arrhythmias and the incidence of SUDEP, prolonging lifespan of Scn1b null mice.

Methods: Wild-type (WT) and null (KO) mice were given daily injections of 10 mg/kg ACE or saline starting at postnatal day 15 (after typical seizure onset) either during the day (09:00) or at night (21:00). In the day group, ECG was recorded daily from P13 until animal death. Starting at P15 mice were recorded both pre- and post- injection to analyze the long-term and acute effects of treatment.

Results: A modest, but significant, increase in survival curves in our KO animals was observed compared to saline treated mice for those given injections during the day (a 2 day increase in median survival). In addition, in this group, the onset of animal death was delayed. To investigate the timing of drug delivery, a subset of mice was given injections at night. In this group there was actually a decrease in lifespan, with an earlier onset of death compared to saline treated mice. On a daily basis from P13, the heart rate (HR) of KO mice was significantly lower than WT but remained steady until the day prior to animal death. HR the day prior to death consistently dropped ~50% (average 414 bpm to 193 bpm) in our saline group; this was prevented in KO animals treated with ACE (421 bpm). Analysis of acute recordings following ACE administration showed that KO mice had a significantly larger reduction in heart rate compared to WT (38% vs. 11%). Further analysis of heart rate variability in these recordings demonstrated that RMSSD (a measure of vagal control of the heart) was reduced in KO mice, with differences in both baseline and following ACE administration.

Conclusions: Leading up to death, we believe it is possible ACE assisted in decreased cardiovascular deficits that could lead to SUDEP and contributed to the modestly increased lifespan. In addition, our results demonstrate the importance of timing in delivery of drugs targeted at SUDEP. Finally, these results suggest that there is a possible hypersensitivity to beta-adrenergic blockade in Scn1b-/- mice.

Funding: This work was supported by a grant from the Research Development Committee at East Tennessee State University and NIH grant R21NS116647 to C.R.F.

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Apr 25th, 9:00 AM Apr 25th, 11:00 AM

Hypersensitive and Circadian Effects of Acebutolol Administration in Scn1b-/- Mice

Culp Center Ballroom

Title: Hypersensitive and circadian effects of acebutolol administration in Scn1b-/- mice.

Rationale: Dravet syndrome (DS) is a severe form of pediatric epilepsy with characterizations of pharmacoresistant seizures and developmental delay. A rarer variant of the DS model is caused by homozygous loss-of-function mutations in SCN1B, which is essential in regulating sodium channel gating, expression, localization, and the firing of action potentials. Mutations in SCN1B result in severe seizures as well as a higher risk of Sudden Unexpected Death in EPilepsy (SUDEP). Factors underlying SUDEP are poorly understood, although cardiac arrhythmias have been implicated. Acebutolol (ACE) is a common beta-blocker used in the treatment of arrhythmias and hypertension. We hypothesized that treating mice with ACE will decrease cardiac arrhythmias and the incidence of SUDEP, prolonging lifespan of Scn1b null mice.

Methods: Wild-type (WT) and null (KO) mice were given daily injections of 10 mg/kg ACE or saline starting at postnatal day 15 (after typical seizure onset) either during the day (09:00) or at night (21:00). In the day group, ECG was recorded daily from P13 until animal death. Starting at P15 mice were recorded both pre- and post- injection to analyze the long-term and acute effects of treatment.

Results: A modest, but significant, increase in survival curves in our KO animals was observed compared to saline treated mice for those given injections during the day (a 2 day increase in median survival). In addition, in this group, the onset of animal death was delayed. To investigate the timing of drug delivery, a subset of mice was given injections at night. In this group there was actually a decrease in lifespan, with an earlier onset of death compared to saline treated mice. On a daily basis from P13, the heart rate (HR) of KO mice was significantly lower than WT but remained steady until the day prior to animal death. HR the day prior to death consistently dropped ~50% (average 414 bpm to 193 bpm) in our saline group; this was prevented in KO animals treated with ACE (421 bpm). Analysis of acute recordings following ACE administration showed that KO mice had a significantly larger reduction in heart rate compared to WT (38% vs. 11%). Further analysis of heart rate variability in these recordings demonstrated that RMSSD (a measure of vagal control of the heart) was reduced in KO mice, with differences in both baseline and following ACE administration.

Conclusions: Leading up to death, we believe it is possible ACE assisted in decreased cardiovascular deficits that could lead to SUDEP and contributed to the modestly increased lifespan. In addition, our results demonstrate the importance of timing in delivery of drugs targeted at SUDEP. Finally, these results suggest that there is a possible hypersensitivity to beta-adrenergic blockade in Scn1b-/- mice.

Funding: This work was supported by a grant from the Research Development Committee at East Tennessee State University and NIH grant R21NS116647 to C.R.F.