Faculty Bibliography

Formaldehyde, a reactive aldehyde widely present in the environment and associated with occupational exposure, has been linked to cognitive impairment and Alzheimer's disease (AD) in multiple epidemiological and animal studies. However, its contribution to AD-like pathology in human neural models remains poorly understood. We utilized a 3D culture system of human neural progenitor cells (ReNcell VM) differentiated into neurons and glial cells to model chronic formaldehyde exposure. Additionally, we established a 3D human AD model by transducing ReN cells with APP and PSEN1 mutations to assess the effects of formaldehyde in an AD genetic background. Long-term formaldehyde exposure (up to 12 weeks) induced a dose-dependent increase in Aβ40, Aβ42, APP, and phosphorylated tau levels in both wild-type and AD-mutant 3D cultures. These changes mimic hallmark features of AD neuropathology, suggesting that formaldehyde acts as a pathological driver in both sporadic and familial contexts. Our study provides direct evidence that chronic formaldehyde exposure may initiate and accelerate amyloid and tau pathologies in 3D human neural cell models. These findings support growing concerns about formaldehyde as a modifiable risk factor in neurodegeneration.

BACKGROUND:Despite the high potential of transcranial ultrasound stimulation (TUS) for non-invasive brain therapy and interrogation, real-time monitoring of brain responses to TUS remains a challenge. Traditional methods to monitor direct neural responses are invasive and mostly incompatible with precise TUS delivery while other non-invasive approaches to visualize the induced responses suffer from poor penetration depth, lack of sensitivity, or low temporal resolution. OBJECTIVE:We present an integrated approach for high precision delivery of ultrasound into the mouse brain and simultaneous whole-brain oximetry with functional optoacoustic tomography to characterize the hemodynamic response elicited by TUS. METHODS:A spherically focused ultrasound array was employed to non-invasively deliver holographic TUS and simultaneously detect multispectral optoacoustic signals from the brains of anesthetized mice. Ultrasound pressure and pulse duration were varied, while the number of stimuli (5), stimulation duration (15 s), and ultrasound frequency (3 MHz) were kept constant. The acquired optoacoustic data were tomographically reconstructed and spectrally unmixed to render three-dimensional maps of oxygenated and deoxygenated hemoglobin in real time. RESULTS:TUS-evoked brain-wide hemodynamics were efficiently monitored via spectroscopic optoacoustic imaging with high spatial and temporal resolution. Holographic TUS targeted to the somatosensory cortex elicited distinct hemodynamic responses, which extended beyond the stimulated region, involving subcortical arteries and pial veins. CONCLUSIONS:Our method provides new transformative non-invasive capabilities to study the effects of ultrasound on a living brain thus help unleash the strong potential of TUS in neuroscience and medicine.

BACKGROUND AND OBJECTIVE/OBJECTIVE:Only a minority of renal oncocytic tumors are aggressive. These tumors' behavior is difficult to predict by histopathological evaluation; consequently, many patients experience anxiety upon diagnosis and may undergo unnecessary treatment. Our aim was to derive genomic and epigenomic signatures to distinguish clinically indolent renal oncocytic tumors from aggressive chromophobe renal cell carcinoma (ChRCC). METHODS:We performed molecular profiling of nephrectomies from 68 patients: 44 with indolent renal oncocytic tumors (19 renal oncocytoma, two oncocytic renal neoplasm of low malignant potential, and 23 indolent ChRCC) and 24 with aggressive ChRCC. We performed targeted exome sequencing, gene expression profiling, and whole-genome methylation sequencing of formalin-fixed, paraffin-embedded (FFPE) samples. We also analyzed The Cancer Genome Atlas Kidney Chromophobe data from 66 ChRCC patients in silico. Genomic and epigenomic signatures linked to aggressive ChRCC-obtained from sampling morphologically nonsarcomatoid foci-from both cohorts were derived using the least absolute shrinkage and selection operator method. KEY FINDINGS AND LIMITATIONS/UNASSIGNED:Aggressive ChRCC was distinguished from indolent ChRCC and other indolent renal oncocytic tumors using a focused seven- to 11-gene expression signature (ten-fold cross-validation [CV] area under the curve [AUC] = 0.77-0.85) with an external validation AUC of 0.88, and an eight-CpG methylation signature (ten-fold CV AUC = 0.86) with an external validation AUC of 0.91. TP53 and PTEN mutations substantially increased the probability of aggressive ChRCC. Limitations include the small sample size. CONCLUSIONS AND CLINICAL IMPLICATIONS/CONCLUSIONS:Focused genomic and epigenomic signatures from routinely processed FFPE tumor tissues can help distinguish aggressive ChRCC from indolent renal oncocytic tumors, including indolent ChRCC. This forms the basis for replication studies to inform appropriate patient management, provide reassurance, and guide follow-up.

Advanced EEG technology has revealed that epileptiform activity occurs more frequently in Alzheimer's disease (AD) than previously recognized, prompting debate over the utility of EEG in AD diagnostics. Yet, unlike epilepsy, epileptiform activity is not always observed in AD, leading to skepticism. Historically, this absence has been attributed to limited recording depth or insufficient recording duration. We tested an alternative hypothesis that certain types of epileptiform activity, specifically high-frequency oscillations (HFOs, defined as 250-500Hz fast ripples), inhibit interictal spikes (IIS), which are currently used to assess hyperexcitability clinically. We recorded wideband (0.1-500Hz) hippocampal local field potentials in three AD (Tg2576, Presenilin 2^-/-, Ts65Dn Down syndrome model) and two epilepsy (intrahippocampal kainic acid, pilocarpine) mouse models during wakefulness and sleep. In both AD and epilepsy, HFOs consistently outnumbered IIS across behavioral states, age and recording contact. However, IIS and HFOs showed divergent relationships: a negative correlation between their rates was observed only in AD, in contrast to a positive correlation in epilepsy. HFOs preceded IIS at much shorter intervals in epilepsy than in AD. Co-occurrence of IIS with ripples did not differ between AD and epilepsy. These findings reveal a novel dissociation between clinically-relevant EEG biomarkers in AD and epilepsy. In AD, HFOs may inhibit IIS, which could lead to underestimation of hyperexcitability and hinder patient stratification for anti-seizure therapies. While non-invasive HFO detection remains challenging, we stress the need for wideband EEG/MEG, particularly in AD, to assess the full extent of hyperexcitability and biomarker interactions that would otherwise remain undetected.

BACKGROUND:Endotracheal intubation in the emergency department (ED) is a critical and time-sensitive procedure requiring both technical skills and cognitive-based reasoning. Evidence on supervised resident-attending dyads with differing years of seniority on decision making during clinical encounters with endotracheal intubations is nascent. OBJECTIVE:To investigate the intersection of postgraduate years in clinical practice between resident and attending supervisor dyads and its associations for clinician choice of laryngoscopy technique and paralytic agent during ED intubations. METHODS:We conducted a retrospective analysis of intubations performed at a multi-site, urban, academic emergency medicine training program, analyzing institutional airway registry data from 2013 to 2023. Using a standardized predictor that accounted for similarity in years of clinical experience within a dyad between a resident and their supervising attending, we performed adjusted mixed-effects logistic regression examining the association of this dyad on two primary outcomes in endotracheal intubation decision making. Our primary outcome measures were the selection of a laryngoscopy technique (either DL or VL), and of a paralytic agent (either short-acting or long-acting) analyzed as categorical variables with a linear mixed effects model, using a binomial response distribution. RESULTS:We examined 2969 intubations for choice of laryngoscopy technique (n = 1117, 37.6 %) and paralytic agent (n = 967, 32.6 %). Higher adjusted odds (aOR) were associated with resident choice of DL over VL when years of experience between residents and supervising attendings were more concordant (aOR 3.05, 95 % CI: 1.1-8.2). Choice of paralytic agent was not associated with differing years of experience. CONCLUSION/CONCLUSIONS:Concordant years of experience between residents and their attendings were associated with technical skill-based laryngoscopy technique choice but not for cognitive-based reasoning in paralytic agent choice among ED intubations, suggesting supervising attending's years in clinical practice may influence decision making during time-sensitive procedures.

Astrocytic Ca²⁺ activity regulates activity-dependent synaptic plasticity, but its role in learning-related synaptic changes in the living brain remains unclear. We found that motor training induced synaptic potentiation on apical dendrites of layer 5 pyramidal neurons, as well as astrocytic Ca²⁺ rises in the mouse motor cortex. Reducing astrocytic Ca²⁺ led to synaptic depotentiation during motor training and subsequent impairment in performance improvement. Notably, synaptic depotentiation occurred on a fraction of dendrites with repetitive dendritic Ca²⁺ activity. On those dendrites, dendritic spines that were active before dendritic Ca²⁺ activity underwent CaMKII-dependent size reduction. In addition, the activation of adenosine receptors prevented repetitive dendritic Ca²⁺ activity and synaptic depotentiation caused by the reduction of astrocytic Ca²⁺, suggesting the involvement of ATP released from astrocytes and adenosine signaling in the processes. Together, these findings reveal the function of astrocytic Ca²⁺ in preventing synaptic depotentiation by limiting repetitive dendritic activity during learning.

OBJECTIVES/OBJECTIVE:To determine the relationships between the number and class of xerogenic medications on whole stimulated salivary flow rates and oral health-related quality of life (OH-QOL) measures in patients who received high-dose external beam radiation therapy (RT) for head and neck cancer (HNC). STUDY DESIGN/METHODS:Complete medication lists were generated using patient electronic health records from every attended study visit for 146 HNC patients. Whole stimulated salivary flow was measured before RT, and 6 and 18-months after RT. Ten single-item questions and two composite scales of swallowing problems and senses problems (taste and smell) were assessed at baseline and at 6-month intervals up to 24 months after RT. Linear mixed-effects models examined associations between the total number and class of medications and stimulated salivary flow and OH-QOL. RESULTS:There was no detected association between the total number of medications and stimulated salivary flow (p-value = .18). Only antidepressant usage was significantly associated with stimulated salivary flow (P = .006). Number of medications, narcotic analgesic, and antidepressant usage were significantly associated with a clinically meaningful decrease in OH-QOL. CONCLUSION/CONCLUSIONS:Antidepressants were associated with reduced stimulated salivary flow, but no cumulative negative effect on whole stimulated salivary flow was identified. Polypharmacy was associated with worse OH-QOL.

Cajal-Retzius (CR) cells are glutamatergic neurons that transiently populate the most superficial layer of the isocortex and allocortex during development, serving an essential role during both prenatal and early postnatal brain development. Notably, these cells disappear from most cortical areas by postnatal day 14 but persist for much longer in the hippocampus. We developed a novel intersectional genetic labeling approach for CR cells that captures almost all of the TRP73-positive CR cells throughout the isocortex and allocortex. This intersectional strategy offers several advantages over previous methods commonly used for CR cell targeting. Here, we applied this new CR cell-labeling strategy to investigate the distribution and persistence of CR cells throughout the whole mouse brain at four different postnatal ages. We observed that the initial CR cell density and the rate of their disappearance vary substantially across different brain areas during development. Strikingly, we observed variation in cell death rate even between adjacent cortical subregions: comparing the medial and the lateral entorhinal cortex, the former retains a high density of CR cells for several months in contrast to the latter. Our results present a necessary revision of the phenomenon of CR cell persistence, showing that, in addition to the hippocampus, several other cortical areas maintain a high density of these cells beyond the first 2 postnatal weeks.

Focused transcranial ultrasound stimulation (TUS) can affect neural activity with high spatial precision, advancing noninvasive neuromodulation toward targeted treatment of brain disorders. Direct monitoring of TUS responses is crucial for ensuring optimal outcomes. Blood-oxygenation-level-dependent (BOLD) functional magnetic resonance imaging has primarily been used for studying TUS effects in both human and nonhuman primate brains. However, the physiology and mechanisms underlying BOLD remain largely unknown due to its highly convoluted nature. To address these limitations, we developed a hybrid system for concurrent optoacoustic and magnetic resonance imaging of TUS (OMRITUS) to comprehensively characterize the hemodynamic changes in murine brains. Our findings reveal paradoxical negative BOLD signals in the activated cortical regions, coupled with increased total hemoglobin levels simultaneously monitored with optoacoustic tomography. Multispectral optoacoustic readings further demonstrated a stronger increase in deoxygenated versus oxygenated hemoglobin, suggesting a potential molecular basis for the negative BOLD responses. OMRITUS enables the study of complex TUS-hemodynamic interactions, paving the way for precise neuromodulatory interventions.