James D. Frost’s research while affiliated with Baylor College of Medicine and other places

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Publications (93)


IGF-1 impacts neocortical interneuron connectivity in epileptic spasm generation and resolution
  • Article

November 2024

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2 Reads

Journal of the American Society for Experimental NeuroTherapeutics

Carlos J. Ballester-Rosado

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John T. Le

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Trang T. Lam

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John W. Swann

IGF-1 IMPACTS NEOCORTICAL INTERNEURON CONNECTIVITY IN EPILEPTIC SPASM GENERATION AND RESOLUTION

October 2024

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4 Reads

Little is known about the mechanisms that generate epileptic spasms following perinatal brain injury. Recent studies have implicated reduced levels of Insulin-like Growth Factor 1 (IGF-1) in these patients brains. Other studies have reported low levels of the inhibitory neurotransmitter, GABA. In the TTX brain injury model of epileptic spasms, we undertook experiments to evaluate the impact of IGF-1 deficiencies on neocortical interneurons and their role in spasms. Quantitative immunohistochemical analyses revealed that neocortical interneurons that express glutamic acid decarboxylase, parvalbumin, or synaptotagmin 2 co-express IGF-1. In epileptic rats, expression of these three interneuron markers were reduced in the neocortex. IGF-1 expression was also reduced, but surprisingly this loss was confined to interneurons. Interneuron connectivity was reduced in tandem with IGF-1 deficiencies. Similar changes were observed in surgically resected neocortex from infantile epileptic spasms syndrome (IESS) patients. To evaluate the impact of IGF-1 deficiencies on interneuron development, IGF-1R levels were reduced in the neocortex of neonatal conditional IGF-1R knock out mice by viral injections. Four weeks later, this experimental maneuver resulted in similar reductions in interneuron connectivity. Treatment with the IGF-1 derived tripeptide, (1-3)IGF-1, abolished epileptic spasms in most animals, rescued interneuron connectivity, and restored neocortical levels of IGF-1. Our results implicate interneuron IGF-1 deficiencies, possibly impaired autocrine IGF-1 signaling and a resultant interneuron dysmaturation in epileptic spasm generation. By restoring IGF-1 levels, (1-3)IGF-1 likely suppresses spasms by rescuing interneuron connectivity. Results point to (1-3)IGF-1 and its analogues as potential novel disease-modifying therapies for this neurodevelopmental disorder.


Experimental timeline and electroencephalographic (EEG) electrode placement. (A) Osmotic minipumps and infusion cannulas were implanted on Postnatal Day (P) 11 or 12. Infusion of tetrodotoxin (TTX) or saline continued for 4 weeks. Once spasms began, electrodes were implanted the day after weaning, and 3 days of baseline spasm counts were obtained during Postnatal Week 4. EEG recordings continued until Week 10, and spasms were analyzed during Weeks 6, 8, and 10. Afterward, behavioral studies commenced. (B) Electrodes were implanted in the cortex in relation to the site of TTX or saline infusion (red plus sign). RA, right cortex anterior to cannula; RL, right lateral; RP, right posterior. Homotopic areas: LA, left anterior; LL, left lateral; LP, left posterior.
Epileptic spasm rats were impaired in object recognition memory and object location memory tasks. Rats were trained for 3 days in testing arenas containing two identical objects. The next day, they were tested for their preference for either a novel object or for one of the original objects that was moved. (A) Object recognition memory: rats with spasms showed less preference for novel object than controls as measured by discrimination index (DI) scores. (B) Object location memory: epileptic spasm rats also showed a decreased preference for the moved object. *p ≤ .05, ***p ≤ .001, two‐sample t‐test; n = 10 in both groups.
Epileptic spasm rats exhibit deficits in the matching to place water maze task. (A) In this task, the location of a hidden platform is changed every day over 5 days, and four trials were run each day to find the platform. Drawings illustrate the perimeter of the water maze and red dots the location of platform. (B) Control rats quickly learned the location of the platform each day (i.e., escape latency decreased by Trial 2), but rats with spasms did not (controls vs. epileptic; p = 1.15E⁻⁴, two‐way analysis of variance with correction for repeated measures). (C) Difference in escape latency between Trials 1 and 2 for control and epileptic spasm rats (*p = .049). Epileptic spasm rats, n = 9; control rats, n = 10.
Evolution of the ictal events of epileptic spasms. (A) Between postnatal Weeks 4 and 10, the frequency of spasms trended toward an increase, but it was not significant. (B) The duration of spasms increased markedly between Weeks 4 and 6 and then plateaued. (C–F) Representative recordings of ictal events in one animal over the 7 weeks of recordings illustrating the evolution of ictal events and increase in duration. In F, components of ictal event: ED, electrodecrement; FA, fast activity; SW, slow wave. The lines above recordings from the left anterior (LA) electrode demark the duration of the ictal events. Recordings from the left lateral recording site were of intermittent high quality and not shown. n = 15 rats. **p ≤ .01, ***p ≤ .001. LP, left posterior; RA, right anterior; RL, right lateral; RP, right posterior.
Comparison of ictal event recordings between Postnatal Weeks 4 and 6. (A,B) comparison of daily spasm counts and spasm duration at these two ages. n = 15 rats. (C,D) comparison of ictal events recorded in four animals. Ictal events during Week 4 were briefer than those from the same animal at Week 6 (notice the different time base for the two panels). (E) Ictal events during Week 4 were also more variable in wave form and on occasion were followed by a focal seizure. Red arrow denotes onset of ictal event and behavioral spasm. **p ≤ .01.

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Neurobehavioral deficits and a progressive ictogenesis in the tetrodotoxin model of epileptic spasms
  • Article
  • Publisher preview available

October 2022

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8 Reads

Objective Our goal was to determine whether animals with a history of epileptic spasms have learning and memory deficits. We also used continuous (24/7) long‐term electroencephalographic (EEG) recordings to evaluate the evolution of epileptiform activity in the same animals over time. Methods Object recognition memory and object location memory tests were undertaken, as well as a matching to place water maze test that evaluated working memory. A retrospective analysis was undertaken of long‐term video/EEG recordings from rats with epileptic spasms. The frequency and duration of the ictal events of spasms were quantified. Results Rats with a history of epileptic spasms showed impairment on the three behavioral tests, and their scores on the object recognition memory and matching to place water maze tests indicated neocortical involvement in the observed impaired cognition. Analysis of EEG recordings unexpectedly showed that the ictal events of spasms and their accompanying behaviors progressively increased in duration over a 2‐week period soon after onset, after which spasm duration plateaued. At the same time, spasm frequency remained unchanged. Soon after spasm onset, ictal events were variable in wave form but became more stereotyped as the syndrome evolved. Significance Our EEG findings are the first to demonstrate progressive ictogenesis for epileptic spasms. Furthermore, in demonstrating cognitive deficits in the tetrodotoxin model, we have met a criterion for an animal model of West syndrome. Animal models will allow in‐depth studies of spasm progression's potential role in cognitive regression and may elucidate why early treatment is considered essential for improved neurodevelopmental outcomes in children.

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A Role for Insulin‐like Growth Factor 1 in the Generation of Epileptic Spasms

April 2022

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13 Reads

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8 Citations

Annals of Neurology

Objective: Infantile spasms is associated with a wide variety of clinical conditions, including perinatal brain injuries. We have created a model in which prolonged infusion of tetrodotoxin (TTX) into the neocortex, beginning in infancy, produces a localized lesion and reproduces the behavioral spasms, EEG abnormalities, and drug responsiveness seen clinically. Here, we undertook experiments to explore the possibility that the growth factor IGF-1 plays a role in generating epileptic spasms. Methods: We combined long-term video EEG recordings with quantitative immunohistochemical and biochemical analyses to unravel IGF-1's role in spasm generation. Immunohistochemistry was undertaken in surgically resected tissue from infantile spasms patients. We used viral injections in neonatal conditional IGF-1R knock-out mice to show that an IGF-1-derived tripeptide, (1-3)IGF-1, acts through the IGF-1 receptor to abolish spasms. Results: Immunohistochemical methods revealed widespread loss of IGF-1 from cortical neurons, but an increase in IGF-1 in the reactive astrocytes in the TTX-induced lesion. Very similar changes were observed in neocortex from spasm patients. In animals, we observed reduced signaling through the IGF-1 growth pathways in areas remote from the lesion. To show the reduction in IGF-1 expression plays a role in spasm generation, epileptic rats were treated with (1-3)IGF-1. We provide three lines of evidence that (1-3)IGF-1 activates the IGF-1 signaling pathway by acting through the receptor for IGF-1. Treatment with (1-3)IGF-1 abolished spasms and hypsarrhythmia-like activity in the majority of animals. Interpretation: Results implicate IGF-1 in the pathogenesis of infantile spasms and IGF-1 analogues as potential novel therapies for this neurodevelopmental disorder. This article is protected by copyright. All rights reserved.


Acthar® Gel (repository corticotropin injection) dose–response relationships in an animal model of epileptic spasms

March 2021

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16 Reads

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7 Citations

Epilepsy & Behavior

Studies were undertaken to evaluate the effectiveness of Acthar® Gel (repository corticotropin injection [RCI]) in the tetrodotoxin (TTX) model of early-life-induced epileptic spasms. Repository corticotropin injection (RCI) is widely used in the United States to treat infantile spasms. A major component of RCI is N25 deamidated ACTH. Additionally, we hoped to provide some insight into the possible role circulating corticosteroids play in spasm cessation by comparing the RCI dose–response relationships for spasm suppression to RCI-induced corticosterone release from the adrenal gland. Spasms were induced by chronic TTX infusion into the neocortex beginning on postnatal day 11. Repository corticotropin injection (RCI) dosages were between 8 and 32 IU/kg/day. Drug titration protocols were used, and comparisons were made to injections of a vehicle gel. Video/EEG recordings (24/7) monitored the drug’s effects continuously for up to 2 months. Tetrodotoxin (TTX)-infused control rats were monitored for the same period of time. In separate experiments, the same dosages of RCI were given to rats and 1 h later plasma was collected and assayed for corticosterone. A parallel study compared the effects of 1-day and 10-day RCI treatments on circulating corticosterone. Results showed that RCI was ineffective at dosages of 8, 12, and 16 IU/kg/day but eliminated spasms in 66% of animals treated with 24 or 32 IU/kg/day. Treating animals with 32 IU/kg/day alone produced the same degree of spasms suppression as observed during the titration protocols. In rats that had hypsarrhythmia-like activity, RCI eliminated this abnormal interictal EEG pattern in all rats that became seizure-free. In terms of plasma corticosterone, 1- and 10-day treatments with RCI produced similar increases in this hormone and the levels increased linearly with increasing dosages of RCI. This stood in sharp contrast to the sigmoid-like dose–response curve for decreases in spasm counts. Our results further validate the TTX model as relevant for the study of infantile spasms. The model should be useful for investigating how RCI acts to eliminate seizures and hypsarrhythmia. Dose–response results suggest that either very high concentrations of circulating corticosteroids are required to abolish spasms or RCI acts through a different mechanism.


Infantile spasms

April 2013

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33 Reads

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37 Citations

Handbook of Clinical Neurology

Infantile spasms are a unique disorder of infancy and early childhood. The average age at onset of infantile spasms is 6 months and the average incidence of the disorder is approximately 0.31 per 1000 live births. Approximately one-quarter of patients will spontaneously stop having spasms within 1 year of onset. There are three main types of epileptic spasms: flexor, extensor, and mixed flexor-extensor. Spasms frequently occur in clusters and commonly occur upon arousal from sleep. The motor spasms are frequently confused with other normal and abnormal infant behaviors. Typically, the interictal EEG reveals hypsarrhythmia or one of its variants. A variety of ictal EEG patterns may be seen, the most common of which is a generalized slow-wave transient followed by an attenuation of the background activity in all regions. The primary treatment objective is to improve the EEG and stop the spasms as soon as possible and to avoid prolonged treatment durations with any form of therapy. Currently, there is no conclusive evidence that medical or surgical treatment of infantile spasms significantly alters long-term outcome. Although the pathophysiological mechanism underlying infantile spasms is unknown, several animal models of infantile spasms have been developed in recent years.


EEG and Quantitative EEG in Mild Traumatic Brain Injury.

December 2012

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77 Reads

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39 Citations

Journal of Neurotrauma

Mild traumatic brain injury (mTBI) causes brain injury resulting in electrophysiologic abnormalities visible in EEG recordings. Quantitative EEG (qEEG) makes use of quantitative techniques to analyze EEG characteristics such as frequency, amplitude, coherence, power, phase and symmetry over time independently or in combination. QEEG has been evaluated for its use in making a diagnosis of mild traumatic brain injury (mTBI) and assessing prognosis, including the likelihood of progressing to the post-concussive syndrome (PCS) phase. Here, we review the EEG and qEEG changes of mTBI described in the literature. An attempt is made to separate the findings seen during the acute, subacute and chronic phases following mTBI. Brief mention is also made of the neurobiological correlates of qEEG using neuro-imaging techniques or in histopathology. Although the literature indicates the promise of qEEG in making a diagnosis and indicating prognosis of mTBI, further study is needed to corroborate and refine these methods.


High Frequency EEG Activity Associated With Ictal Events in an Animal Model of Infantile Spasms

January 2011

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33 Reads

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44 Citations

To describe high frequency (HF) electrographic activity accompanying ictal discharges in the tetrodotoxin (TTX) model of infantile spasms. Previous studies of HF oscillations in humans and animals suggest that they arise at sites of seizure onset. We compared HF oscillations at several cortical sites to determine regional differences. Methods:  TTX was infused for 4 weeks into the neocortex of rats beginning on postnatal days 11 or 12. Electroencephalography (EEG) electrodes were implanted 2 weeks later and video-EEG recordings were analyzed between postnatal days 31 and 47. EEG recordings were digitally sampled at 2,048 Hz. HF EEG activity (20-900 Hz) was quantified using compressed spectral arrays and band-pass filtering.   Multiple seizures were analyzed in 10 rats. Ictal onset was associated with multiple bands of rhythmic HF activity that could extend to 700 Hz. The earliest and most intense discharging typically occurred contralaterally to where TTX was infused. HF activity continued to occur throughout the seizure (even during the electrodecrement that is recorded with more traditional filter settings), although there was a gradual decrease of the intensity of the highest frequency components as the amplitude of lower frequency oscillations increased. Higher frequencies sometimes reappeared in association with spike/sharp-waves at seizure termination. The findings show that HF EEG activity accompanies ictal events in the TTX model. Results also suggest that the seizures in this model do not originate from the TTX infusion site. Instead HF discharges are usually most intense and occur earliest contralaterally, suggesting that these homologous regions may be involved in seizure generation.


A Multistage System for the Automated Detection of Epileptic Seizures in Neonatal Electroencephalography

September 2009

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100 Reads

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90 Citations

Journal of Clinical Neurophysiology

This paper describes the design and test results of a three-stage automated system for neonatal EEG seizure detection. Stage I of the system is the initial detection stage and identifies overlapping 5-second segments of suspected seizure activity in each EEG channel. In stage II, the detected segments from stage I are spatiotemporally clustered to produce multichannel candidate seizures. In stage III, the candidate seizures are processed further using measures of quality and context-based rules to eliminate false candidates. False candidates because of artifacts and commonly occurring EEG background patterns such as bifrontal delta activity are also rejected. Seizures at least 10 seconds in duration are considered for reporting results. The testing data consisted of recordings of 28 seizure subjects (34 hours of data) and 48 nonseizure subjects (87 hours of data) obtained in the neonatal intensive care unit. The data were not edited to remove artifacts and were identical in every way to data normally processed visually. The system was able to detect seizures of widely varying morphology with an average detection sensitivity of almost 80% and a subject sensitivity of 96%, in comparison with a team of clinical neurophysiologists who had scored the same recordings. The average false detection rate obtained in nonseizure subjects was 0.74 per hour.


A Triplet Repeat Expansion Genetic Mouse Model of Infantile Spasms Syndrome, Arx((GCG)10+7), with Interneuronopathy, Spasms in Infancy, Persistent Seizures, and Adult Cognitive and Behavioral Impairment

August 2009

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18 Reads

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171 Citations

The Journal of Neuroscience : The Official Journal of the Society for Neuroscience

Infantile spasms syndrome (ISS) is a catastrophic pediatric epilepsy with motor spasms, persistent seizures, mental retardation, and in some cases, autism. One of its monogenic causes is an insertion mutation [c.304ins (GCG)(7)] on the X chromosome, expanding the first polyalanine tract of the interneuron-specific transcription factor Aristaless-related homeobox (ARX) from 16 to 23 alanine codons. Null mutation of the Arx gene impairs GABA and cholinergic interneuronal migration but results in a neonatal lethal phenotype. We developed the first viable genetic mouse model of ISS that spontaneously recapitulates salient phenotypic features of the human triplet repeat expansion mutation. Arx((GCG)10+7) ("Arx plus 7") pups display abnormal spasm-like myoclonus and other key EEG features, including multifocal spikes, electrodecremental episodes, and spontaneous seizures persisting into maturity. The neurobehavioral profile of Arx mutants was remarkable for lowered anxiety, impaired associative learning, and abnormal social interaction. Laminar decreases of Arx+ cortical interneurons and a selective reduction of calbindin-, but not parvalbumin- or calretinin-expressing interneurons in neocortical layers and hippocampus indicate that specific classes of synaptic inhibition are missing from the adult forebrain, providing a basis for the seizures and cognitive disorder. A significant reduction of calbindin-, NPY (neuropeptide Y)-expressing, and cholinergic interneurons in the mutant striatum suggest that dysinhibition within this network may contribute to the dyskinetic motor spasms. This mouse model narrows the range of critical pathogenic elements within brain inhibitory networks essential to recreate this complex neurodevelopmental syndrome.


Citations (76)


... Previously, we reported a widespread loss of IGF-1 in the neocortex of animals with spasms (32). Similar alterations in IGF-1 expression were observed in surgically resected neocortices from symptomatic IESS patients. ...

Reference:

IGF-1 IMPACTS NEOCORTICAL INTERNEURON CONNECTIVITY IN EPILEPTIC SPASM GENERATION AND RESOLUTION
A Role for Insulin‐like Growth Factor 1 in the Generation of Epileptic Spasms
  • Citing Article
  • April 2022

Annals of Neurology

... Furthermore, it can be difficult for providers to diagnose swallowing disorders because the symptoms are often absent, subtle, nonspecific, and heterogeneous [21], and it is especially difficult if the patient is experiencing silent aspiration. Silent aspiration is common in children with neurological disorders [22][23][24], which can be associated with varying severity of chronic aspiration that is likely due to dysregulation of the swallowing and glottal closure reflexes along with the inability to coordinate the pharyngeal and esophageal phases of swallowing [25]. The significance of silent aspiration in those infants who are thriving well without any aerodigestive, neurological or cardiopulmonary diseases is unclear. ...

Gastroesophageal Reflux and Apnea
  • Citing Article
  • December 1983

Pediatrics

... In these animals, epileptic spasms are induced in rats by infusion of TTX into the cortex beginning in infancy (29). Within one week, animals begin to display epileptic spasms that have neurophysiological and behavioral features and pharmacological sensitivities equivalent to those of humans (29)(30)(31). ...

Acthar® Gel (repository corticotropin injection) dose–response relationships in an animal model of epileptic spasms
  • Citing Article
  • March 2021

Epilepsy & Behavior

... As an example of this, we can use epileptic spasms in infancy (infantile spasms, loosely West syndrome), which clinically look very similar, but etiopathogenesis in their symptomatic subgroup covers over 200 different causes. 2 Plus, there is also the cryptogenic subgroup, which slowly rises from its genetic underlayment. Current treatments are far from the mechanistic or rather causative approach: Currently used drugs are antiseizure medications suppressing, if effective, just one component of the syndrome. ...

Infantile Spasms
  • Citing Book
  • January 2003

... Our group previously reported immunological disturbances in patients with WS and LGS, consisting of impairment in T cell subclasses, T cell functional tests, in vivo skin sensitization tests and immunoglobulin levels and the demonstration of the presence of antibody to brain extract in the sera of WS and LGS children [13][14][15][16][17] . Other authors have described similar findings recently [18][19][20][21] . ...

Immunological evaluation of patients with infantile spasms, abstract
  • Citing Article
  • January 1985

Annals of Neurology

... More importantly, the presence or absence of ictal motor symptoms was explained by the amplitude of ictal HFOs in the Rolandic area rather than that in the seizure onset zone. These novel observations suggest that augmentation of HFOs in the Rolandic area is the causative predictor of motor manifestations during spasms and further support the hypothesis that not (or not exclusively) brainstem (Hrachovy and Frost, 1989) but cortical activation is primarily responsible for the semiology of epileptic spasms (Gaily et al., 1995;Asano et al., 2005). Previous ECoG studies reported that voluntary movement of the hand and passive movement of the hand by electrical stimulation can augment HFOs in the Rolandic area (Crone et al., 1998;Fukuda et al., 2008;Nagasawa et al., 2010), but it is unlikely that augmentation of ictal HFOs seen in the present study purely represented the results from motor manifestations, since significant augmentation of HFOs occurred approximately 400 msec prior to the EMG onset. ...

Infantile Spasms
  • Citing Article
  • April 1989

Pediatric Clinics of North America

... Reductions in alpha and beta amplitudes have been associated with diminished cognitive function (Thatcher, et al., 1998). Mild, diffuse reduction in the alpha band mean frequency is a common EEG abnormality that is observed in TBI patients (Koufen & Dichgans, 1978;Haneef, et al., 2012;;Schmitt & Dichter, 2015;Tebano, et al., 1988;von Bierbrauer, et al., 1992). Tebano and colleagues reported reductions of fast beta (20-35 Hz) mean frequency 3-10 days following mild TBI compared with normal controls (Tebano, et al., 1988). ...

EEG and Quantitative EEG in Mild Traumatic Brain Injury.
  • Citing Article
  • December 2012

Journal of Neurotrauma

... Different variants of hypsarrhythmia have been reported further than its typical presentation; these include (1) hypsarrhythmia with increased interhemispheric synchronization, (2) asymmetric hypsarrhythmia, (3) hypsarrhythmia with episodes of voltage attenuation, (4) hypsarrhythmia with a consistent focus of epileptic discharges or focal slowing, and others [22]. ...

Infantile spasms
  • Citing Article
  • April 2013

Handbook of Clinical Neurology