The Heart of Helping: Psychological and Physiological Effects of Contrasting Coaching Interactions

Passarelli, Angela M.

11 June 2014

No description available.

Organizational Behavior

Physiological Linkage and Affective Dynamics in Dyadic Interactions Between Adolescents and Their Depressed Mothers

McKillop, Hannah N.

09 February 2015

No description available.

Psychology

respiratory sinus arrhythmia

skin conductance

parent-child interactions

depression

physiological linkage

Unveiling Mechanisms Involved in Non-Traditional Cases of Inherited Cardiac Channelopathies

Hoshi, Malcolm

03 September 2015

No description available.

Physiology

Biophysics

cardiac arrhythmia

channelopathy

Long QT Syndrome

Brugada Syndrome

variable penetrance

Individual Periodic Limb Movements with Arousal Trigger Non-sustained Ventricular Tachycardia: A Case-Crossover Analysis

May, Anna Michelle

01 February 2018

No description available.

Health Sciences

Investigating the mechanism underlying CaMKII-induced arrhythmias in ischemia using optical mapping

Howard, Taylor

24 August 2018

No description available.

Biomedical Engineering

CaMKII

ischemia reperfusion

late sodium current

optical mapping

arrhythmia

Modulation of the Arrhythmia Substrate in Cardiovascular Disease

Long, Victor P., III

12 September 2016

No description available.

Pharmacy Sciences

heart failure

sinus node

adenosine

potassium current

arrhythmia

hypokalemia

pharmacist

cellular electrophysiology

An Interpersonal Model of Depression: A Psychophysiological Perspective

Pritchard, Kelsey Jay

24 May 2016

No description available.

Clinical Psychology

Physiological Psychology

Psychology

depression

excessive reassurance seeking

social support

stress

respiratory sinus arrhythmia

Engineering an Anti-arrhythmic Calmodulin

Walton, Shane David

26 September 2016

No description available.

Biophysics

calmodulin

protein engineering

cardiac arrhythmia

CPVT

LQTS

ryanodine receptor regulation

AAV9

The Role of CASQ2^D307H Mutant protein in Catecholamine Induced Polymorphic Ventricular Tachycardia (CPVT)

Kalyanasundaram, Anuradha

January 2009

No description available.

Biology

Biomedical Research

Cellular Biology

Calcium

arrhythmia

protein conformation

mutation

CPVT

The Voltage Gated Sodium Channel β1/β1B subunits: Emerging Therapeutic Targets in the Heart

Williams, Zachary James

11 January 2024

Voltage-gated sodium channels are composed of pore-forming α-subunits, and modulatory and multifunctional associated β subunits. While much of the field of cardiac electrophysiology and pathology has focused on treating and preventing cardiac arrhythmias by targeting the α subunit, there is also evidence that targeting the β subunits, particularly SCN1B, the gene that encodes β1 and an alternatively spliced variant β1B, has therapeutic potential. The first attempt at targeting the β1 subunit was with the generation of and treatment with an SCN1B Ig domain mimetic peptide βadp1. Here we describe further investigation into the function and mode-of-action of both βadp1 and novel peptides derived from the original βadp1 sequence. We find that in a heterologous expression system βadp1 initially disrupts β1-mediated trans-homophilic adhesion, but after approximately 30 hours eventually increases adhesion. Novel mimetic dimers increase β1 adhesion up to 48 hours post-treatment. Furthermore, it appears that βadp1 may increase β1 adhesion by upregulating the intramembrane proteolysis of β1, a process which has important downstream implications and effects on translation. Despite these exciting findings, we were unable to translate them into a primary culture of cardiac cells with endogenous expression of β1 because we found that both neonatal rat cardiomyocytes and isolated adult mouse cardiomyocytes do not express β1 at detectable levels, whereas they do appear to express β1B. In summary, we show exciting findings on the function and mode-of-action of SCN1B mimetic peptides and their therapeutic potential in targeting the β1 subunit, but further work is needed to determine the translatability of our findings to in vivo models and eventually to humans. / Doctor of Philosophy / Voltage-gated sodium channels have two main parts: the pore-forming α-subunits and the modulatory β subunits. Most research in heart function and issues has focused on fixing problems with the α subunit. However, there's evidence that working on the β subunits, specifically the SCN1B gene that makes β1 and another version called β1B, could be helpful. Previously, researchers used a peptide that is designed exactly like a part of β1, called βadp1, to target the β1 subunit. In our study, we explore more about how βadp1 works and test new peptides based on βadp1. We found that βadp1 initially disrupts trans-homophilic adhesion, where 2 β1 subunits interact with each other across the space between 2 cells, but after about 30 hours, it actually increases adhesion. New mimetic dimers also boost adhesion up to 48 hours later. It seems like βadp1 might enhance adhesion by triggering a process called intramembrane proteolysis of β1, which has important effects on translation. Despite these exciting findings, we couldn't confirm the presence of this protein in heart cells because we discovered that certain heart cells don't have enough β1, although they do have β1B. In conclusion, our study shows promising results about how SCN1B mimetic peptides work and their potential for treating arrhythmia. However, more research is needed to see if these findings apply to real-life situations and eventually to help people with cardiac conduction abnormalities.

Voltage-gated sodium channels

SCN1B (β1/β1B)

peptide therapeutics

arrhythmia

sudden cardiac death