Frequency-dependent Increase Research Articles

Enhanced mechanical and damping properties of Cu-Modified Al-Ni eutectic alloys: Solid-solution and precipitation hardening effects

The study aimed to analyze the mechanical properties, precipitation strengthening, and microstructure of Al-Ni-Cu alloys to understand their enhanced characteristics. Additionally, the damping behavior was examined using a dynamic mechanical analyzer across a continuous heating temperature range with frequencies from 0.5 to 15 Hz. The experimental results indicate that the Al-Ni eutectic alloy, which exhibits an ultrafine Al3Ni intermetallic fiber-reinforced Al matrix, transitions to a dendritic-ultrafine eutectic composite structure. The Cu-containing alloys exhibit two distinct primary phases: α-Al and Al-Ni-Cu ternary intermetallic compounds. The eutectic matrix transforms from Al-Al3Ni to Al-Al7Cu4Ni, and subsequently to Al-Al2Cu. These microstructural evolutions result in an enhancement of the tensile yield strength from 170 MPa to 440 MPa, with additional hardening achieved through aging-induced precipitation. Moreover, the damping capacity improves with the addition of Cu at elevated temperatures, and there is an increase in frequency dependence. This paper will discuss the microstructural features, mechanical properties, deformation behaviors, and damping properties in detail.

Aging disrupts locus coeruleus-driven norepinephrine transmission in the prefrontal cortex: Implications for cognitive and motor decline.

The locus coeruleus (LC)-prefrontal cortex (PFC) circuitry is crucial for cognition, planning, posture and mobility. This study examines the role of norepinephrine (NE) in elucidating the neurobiological basis of age-related cognitive and motor declines. Aged mice exhibited reduced spatial learning, impaired memory, decreased physical endurance, and notable changes in locomotor behavior. The neurochemical foundations of these deficits were investigated through fast-scan cyclic voltammetry to measure NE release in the PFC and LC, both invivo and in brain slices. Additionally, oxygen levels were monitored as a proxy for PFC neuronal function, and NE levels were analyzed in the extracellular space via microdialysis and total content in the PFC. Aged mice exhibited a frequency-dependent increase in NE release in the PFC upon LC stimulation, suggesting alterations in neural responsiveness due to aging. We also recorded slower NE reuptake rates and increased NE content and neuronal activity, indicated by higher oxygen levels and facilitated neuron activation due to membrane depolarization recorded via whole-cell patch-clamp. To understand the basis for LC-driven NE surges in the PFC with aging, we examined the expression levels of two proteins critical for presynaptic NE release and NE reuptake: the α2a-adrenergic receptor and the NE transporter. Both showed a significant decrease in the PFC with aging. These findings support the concept that aging significantly alters the structural and functional dynamics within the LC-PFC neural circuit, impacting NE modulation and neuronal activity, which may underlie the observed declines in cognitive and motor functions in aging populations.

Structural and dielectric analysis of Cu-doped NiCo2O4 nanoparticles synthesized by green synthesis approach

The synthesis process of nanoparticles profoundly influences the chemical and physical properties of materials. Green synthesis, utilizing plant extracts as precursor materials, presents an environmentally friendly approach for producing metal oxide nanoparticles. In this study, we synthesized copper-doped nickel cobaltite (Ni1-xCuxCo2O4, x = 0.5) nanoparticles via a green synthesis method employing aloe vera leaf extract. Analysis of the XRD pattern revealed the formation of cubic spinel Ni0.5Cu0.5Co2O4 nanoparticles well-crystalline in nature (space group: Fd-3 m), free from secondary impurity phases. Crystalline size, determined using Debye Scherrer, modified Scherrer, and Williamson-Hall models, yielded values of ∼ 27 nm, ∼ 35 nm, and ∼ 62 nm, respectively. Dielectric studies conducted at room temperature revealed a frequency-dependent increase in dielectric constant. At lower frequencies, tangent loss (tan δ) showed higher values, which gradually decreased as frequency increased. Additionally, the AC conductivity demonstrated a significant increase with higher external field frequencies.

Optogenetic stimulation of Phox2b-expressing neurons in the respiratory parafacial region rescue fentanyl-induced respiratory depression

The primary cause of death from opioid overdose is opioid-induced respiratory depression (OIRD), which results in substantial suppression of respiratory rate, destabilization of breathing patterns, severe hypercapnia, and a heightened risk for life-threatening apnea. A crucial chemosensitive brainstem region, located in the rostral ventrolateral medullary reticular formation, contains a bilateral cluster of approximately 800 non-opioid receptor-expressing glutamatergic, non-catecholaminergic, Phox2b+ propriobulbar neurons. These neurons are stimulated by CO2 and acidification and play a vital role in regulating breathing to prevent respiratory acidosis. Under normal circumstances, opioid induced hypercapnia should stimulate these cells to restore ventilation and prevent disturbances in arterial blood gases. However, during OIRD, it remains unclear whether these neurons can effectively rescue breathing in the response to opioid induced hypercapnia. The present study aims to address this question by investigating whether the ability of these neurons to stimulate breathing is significantly altered during opioid-induced respiratory depression. Using optogenetic stimulation, we stimulated these Phox2b+ cells before and after fentanyl to test for whether their ability to stimulate ventilation is reduced during OIRD. As expected, fentanyl (500 μg/kg, ip) resulted in respiratory rate suppression and destabilization of breathing pattern. Before fentanyl administration optogenetic stimulation of Phox2b+ cells increased breathing activity in a pulse stimulation frequency dependent (5-20Hz) manner. Unexpectedly, following fentanyl administration, similar optogenetic stimulation of Phox2b+ cells resulted in a significantly greater frequency dependent (5-20Hz) increase in breathing activity compared to pre-fentanyl levels. Additionally, both hypercapnia (FiCO2 = 0.1) or hypoxia (FiO2 = = 0.1) produced an increase breathing activity in a similar manner in pre- and post-fentanyl conditions. The results suggest that fentanyl paradoxically increases the ability of Phox2b+ cells to stimulate breathing but shifts the steady-state relationship between ventilation and arterial blood gases, such that resting ventilation is reduced. FAPESP, NIH. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Flicker light stimulation induces thalamocortical hyperconnectivity with LGN and higher-order thalamic nuclei

Abstract The thalamus is primarily known as a relay for sensory information; however, it also critically contributes to higher-order cortical processing and coordination. Thalamocortical hyperconnectivity is associated with hallucinatory phenomena that occur in various psychopathologies (e.g., psychosis, migraine aura) and altered states of consciousness (ASC; e.g., induced by psychedelic drugs). However, the exact functional contribution of thalamocortical hyperconnectivity in forming hallucinatory experiences is unclear. Flicker light stimulation (FLS) can be used as an experimental tool to induce transient visual hallucinatory phenomena in healthy participants. Here, we use FLS in combination with fMRI to test how FLS modulates thalamocortical connectivity between specific thalamic nuclei and visual areas. We show that FLS induces thalamocortical hyperconnectivity between lateral geniculate nucleus (LGN), early visual areas, and proximal upstream areas of the ventral visual stream (e.g., hV4, VO1). Further, an exploratory analysis indicates specific higher-order thalamic nuclei, such as anterior and mediodorsal nuclei, to be strongly affected by FLS. Here, the connectivity changes to upstream cortical visual areas directly reflect a frequency-dependent increase in experienced visual phenomena. Together, these findings contribute to the identification of specific thalamocortical interactions in the emergence of visual hallucinations.

Polysaccharide-addition order regulates sonicated egg white peptide stabilized nanoemulsions and β-carotene digestion in vitro

In this paper, the effects of the polysaccharide-addition order (before and after homogenisation) on the stability of nanoemulsion stabilised by sonicated egg white peptides and the in vitro digestive behaviour of loaded β-carotene were investigated. The pyrene fluorescence results showed that the concentration of micelles formed by flaxseed gum (FG) in complex with peptides was significantly higher than that of peach gum (PG). The order of polysaccharide-addition affected the emulsion properties and stability; adding polysaccharides before homogenisation led to protein bridging flocculation, low polysaccharide coverage and a higher interfacial adsorbed protein content of the emulsion. PG enhanced potential spatial resistance and electrostatic repulsion, effectively prevented emulsion flocculation and improved electrostatic stability. After homogenisation, FG was added to emulsions to improve environmental stability, including ionic, temperature and storage stability. Due to the viscosity of polysaccharides and the formed polysaccharide-protein-lipid aggregates, the increasing degree of bridging flocculation promoted the prominent of apparent viscosity, and the Gʹ and Gʹʹ exhibited a frequency-dependent increase. The polysaccharide type and mode changed the surface loading charge and droplet interface thickness, delayed the destruction of the droplet structure by protease, and slowed the release of β-carotene to form micelles. In this study, a stable emulsion system and an efficient emulsion transport system for bioactive substances were obtained by regulating polysaccharides adding order, which is significant for constructing an efficient food emulsion delivery system.

Renal Sympathetic Hyperactivity in Diabetes Is Modulated by 5-HT1D Receptor Activation via NO Pathway.

Renal vasculature, which is highly innervated by sympathetic fibers, contributes to cardiovascular homeostasis. This renal sympathetic outflow is inhibited by 5-HT in normoglycaemic rats. Considering that diabetes induces cardiovascular complications, we aimed to determine whether diabetic state modifies noradrenergic input at renal level and its serotonergic modulation in rats. Alloxan diabetic rats were anaesthetized (pentobarbital; 60 mg/kg i.p.) and prepared for in situ autoperfusion of the left kidney to continuously measure systemic blood pressure (SBP), heart rate (HR), and renal perfusion pressure (RPP). Electrical stimulation of renal sympathetic outflow induces frequency-dependent increases (Δ) in RPP (23.9 ± 2.1, 59.5 ± 1.9, and 80.5 ± 3.5 mm Hg at 2, 4, and 6 Hz, respectively), which were higher than in normoglycaemic rats, without modifying HR or SBP. Intraarterial bolus of 5-HT and 5-CT (5-HT1/5/7 agonist) reduced electrically induced ΔRPP. Only L-694,247 (5-HT1D agonist) reproduced 5-CT inhibition on sympathetic-induced vasoconstrictions, whereas it did not modify exogenous noradrenaline-induced ΔRPP. 5-CT inhibition was exclusively abolished by i.v. bolus of LY310762 (5-HT1D antagonist). An inhibitor of guanylyl cyclase, ODQ (i.v.), completely reversed the L-694,247 inhibitory effect. In conclusion, diabetes induces an enhancement in sympathetic-induced vasopressor responses at the renal level. Prejunctional 5-HT1D receptors, via the nitric oxide pathway, inhibit noradrenergic-induced vasoconstrictions in diabetic rats.

Tensile strain and altered synovial tissue metabolism in human knee osteoarthritis

Synovium is critical for maintaining joint homeostasis and may contribute to mechanobiological responses during joint movement. We investigated mechanobiological responses of whole synovium from patients with late-stage knee osteoarthritis (OA). Synovium samples were collected during total knee arthroplasty and assigned to histopathology or cyclic 10% tensile strain loading, including (1) static (control); (2) low-frequency (0.3 Hz); and iii) high-frequency (1.0 Hz) for 30-min. After 6-h incubation, tissues were bisected for RNA isolation and immunostaining (3-nitrotyrosine; 3-NT). RNA sequencing was analyzed for differentially expressed genes and pathway enrichment. Cytokines and lactate were measured in conditioned media. Compared to controls, low-frequency strain induced enrichment of pathways related to interferon response, Fc-receptor signaling, and cell metabolism. High-frequency strain induced enrichment of pathways related to NOD-like receptor signaling, high metabolic demand, and redox signaling/stress. Metabolic and redox cell stress was confirmed by increased release of lactate into conditioned media and increased 3-NT formation in the synovial lining. Late-stage OA synovial tissue responses to tensile strain include frequency-dependent increases in inflammatory signaling, metabolism, and redox biology. Based on these findings, we speculate that some synovial mechanobiological responses to strain may be beneficial, but OA likely disturbs synovial homeostasis leading to aberrant responses to mechanical stimuli, which requires further validation.

Abstract P1065: Deletion Of Arginine 14 Increases Phospholamban Oligomerization And Disrupts The Cardiac Force-Frequency Relationship

The Bowditch effect is a physiological phenomenon where accelerated cardiac pacing leads to an increase in the contractile force of the heart. While this has largely been attributed to a frequency-dependent increase in L-type calcium channel influx, evidence suggests intracellular calcium handling proteins must also play an active role. Knock-out of phospholamban (PLB), the inhibitor of the Ca ATPase (SERCA), virtually abolishes the Bowditch effect in mice, suggesting PLB is a major determinant of the cardiac force-frequency relationship. However, no molecular mechanism has explained this frequency-dependent function of PLB. Our lab has previously shown that SERCA loses affinity for PLB when intracellular calcium is elevated. Here, FRET microscopy revealed dynamic decreases in PLB-SERCA binding in response to intracellular calcium elevations. PLB monomers freed from SERCA were rapidly incorporated into PLB pentamers. Interestingly, unbinding of PLB from pentamers was very slow and delayed the recovery of PLB-SERCA complexes by several seconds after calcium elevations. In a computational model of these regulatory binding dynamics, PLB pentamers sequestered inhibitory monomers away from SERCA at fast heart rates. By lowering PLB inhibition of SERCA with increasing cardiac pacing, PLB pentamers serve as a major contributor to the Bowditch effect. Notably, deletion of arginine 14 of PLB causes arrhythmogenic cardiomyopathy and has been thought to destabilize PLB pentamers. Surprisingly, we found R14del-PLB enhanced pentamer stability and slowed the rate of PLB exchange from pentamers to SERCA. We hypothesize that R14del mutation may disrupt frequency-dependent changes in SERCA regulation by PLB during exercise.

The slow release behavior of soy protein isolate/κ-carrageenan composite hydrogel: Effect of konjac glucomannan

Composite hydrogels are known for their potential applications in drug delivery fields. Pure κ-carrageenan (KC) hydrogels have a drug burst release behavior, which greatly limit their applications. In this study, konjac glucomannan (KGM) was used to further improve the properties of soy protein isolate (SPI)/KC composite hydrogels. The results showed that the viscoelasticity of the composite hydrogels increased at KC/KGM ratio 9:1 due to the increase of hydrogen bond interaction. Excessive addition of KGM in composite hydrogels led to the increase in frequency dependence and gel network cavity as well as the decrease in gel cohesiveness. In vitro study on glucose release behavior of composite hydrogels showed that the glucose slow release behavior was enhanced by a small amount of KGM incorporation and had highly positive correlation with the gel viscoelasticity. These results suggested that KGM had the potential to enhance the properties and drug release characteristics of composite hydrogels.

Nanoenviroments of the β-Subunit of L-Type Voltage-Gated Calcium Channels in Adult Cardiomyocytes.

In cardiomyocytes, Ca2+ influx through L-type voltage-gated calcium channels (LTCCs) following membrane depolarization regulates crucial Ca2+-dependent processes including duration and amplitude of the action potentials and excitation-contraction coupling. LTCCs are heteromultimeric proteins composed of the Cavα1, Cavβ, Cavα2δ and Cavγ subunits. Here, using ascorbate peroxidase (APEX2)-mediated proximity labeling and quantitative proteomics, we identified 61 proteins in the nanoenvironments of Cavβ2 in cardiomyocytes. These proteins are involved in diverse cellular functions such as cellular trafficking, cardiac contraction, sarcomere organization and excitation-contraction coupling. Moreover, pull-down assays and co-immunoprecipitation analyses revealed that Cavβ2 interacts with the ryanodine receptor 2 (RyR2) in adult cardiomyocytes, probably coupling LTCCs and the RyR2 into a supramolecular complex at the dyads. This interaction is mediated by the Src-homology 3 domain of Cavβ2 and is necessary for an effective pacing frequency-dependent increase of the Ca2+-induced Ca2+ release mechanism in cardiomyocytes.

Activation of the Organum Vasculosum of the Lamina Terminalis Produces a Sympathetically Mediated Hypertension.

Neurons in the organum vasculosum of the lamina terminalis (OVLT) sense extracellular NaCl and angiotensin II concentrations to regulate body fluid homeostasis and arterial blood pressure. Lesion of the anteroventral third ventricular region or OVLT attenuates multiple forms of neurogenic hypertension. However, the extent by which OVLT neurons directly regulate sympathetic nerve activity to produce hypertension is not known. Therefore, the present study tested this hypothesis by using a multi-faceted approach including optogenetics, single-unit and multifiber nerve recordings, and chemogenetics. First, optogenetic activation of OVLT neurons in conscious Sprague-Dawley rats (250-400 g) produced frequency-dependent increases in arterial blood pressure and heart rate. These responses were not altered by the vasopressin receptor antagonist (β-mercapto-β,β-cyclopentamethylenepropionyl1,O-me-Tyr2,Arg8)-vasopressin but eliminated by the ganglionic blocker chlorisondamine. Second, optogenetic activation of OVLT neurons significantly elevated renal, splanchnic, and lumbar sympathetic nerve activity. Third, single-unit recordings revealed optogenetic activation of the OVLT significantly increased the discharge of bulbospinal, sympathetic neurons in the rostral ventrolateral medulla. Lastly, chronic chemogenetic activation of OVLT neurons for 7 days significantly increased 24-hour fluid intake and mean arterial blood pressure. When the 24-hour fluid intake was clamped at baseline intakes, chemogenetic activation of OVLT neurons still produced a similar increase in arterial blood pressure. Neurogenic pressor activity assessed by the ganglionic blocker chlorisondamine was greater at 7 days of OVLT activation versus baseline. Collectively, these findings indicate that acute or chronic activation of OVLT neurons produces a sympathetically mediated hypertension.

Temperature (but not acclimation) affects hearing in fishes adapted to different temperature regimes

Temperature affects various metabolic and physiological processes in ectothermic animals, including auditory systems. The current study investigates the effect of temperature and thermal acclimation time on hearing sensitivities in a eurythermal and a stenothermal fish possessing accessory hearing structures. Using the auditory evoked potential (AEP) recording technique, we determined thresholds from 0.1 to 4 kHz and peak latencies of AEP-waveforms in response to a click stimulus. The goldfish Carassius auratus was chosen as a model for eurythermal and the Amazonian catfish Megalodoras uranoscopus as a model for stenothermal species. Both species were tested at two different temperatures (C. auratus: 15 °C and 25 °C, M. uranoscopus: 22 °C and 30 °C) and acclimation periods, within 22 h (unacclimated) or three to four weeks (acclimated) after reaching the target temperature. A frequency-dependent increase in auditory sensitivity and a decrease of peak latencies was recorded in both species at higher temperatures, independent of acclimation time. The change in hearing thresholds per degree Celsius was more pronounced in the stenothermal catfish. The data indicate that higher temperatures improved hearing (lower thresholds, shorter latencies), whereas acclimation had no effect on hearing in either species. The latter data contradict previous findings in the eurythermal channel catfish Ictalurus punctatus in which acclimation slightly improved hearing when raising the temperatures. A comparison of changes in hearing sensitivity per degree Celsius of all seven species tested so far revealed no differences between eurythermal and stenothermal species.

Differential Effect of Non-Thermal Plasma RONS on Two Human Leukemic Cell Populations.

Simple SummaryAs the number of investigations into the use of non-thermal plasma (NTP) for cancer treatment expands, it is becoming apparent that susceptibility of different cancer cells to NTP varies. We hypothesized that such differences could be attributed to the cell type-dependent interactions between NTP-generated reactive oxygen and nitrogen species (RONS) and the target cells. To test this hypothesis, we examined how two different human leukemic cell lines—Jurkat T lymphocytes and THP-1 monocytes—influence hydrogen peroxide and nitrite content in media after NTP exposure. We also assessed the potential of NTP to enhance immunogenicity in these cells and assayed phagocytosis of NTP-exposed leukemic cells by macrophages. Our results highlight the significance of target-mediated modulation of plasma chemical species in the development and clinical use of protocols involving plasma sources for use in cancer therapeutic application.Non-thermal plasma application to cancer cells is known to induce oxidative stress, cytotoxicity and indirect immunostimulatory effects on antigen presenting cells (APCs). The purpose of this study was to evaluate the responses of two leukemic cell lines—Jurkat T lymphocytes and THP-1 monocytes—to NTP-generated reactive oxygen and nitrogen species (RONS). Both cell types depleted hydrogen peroxide, but THP-1 cells neutralized it almost immediately. Jurkat cells transiently blunted the frequency-dependent increase in nitrite concentrations in contrast to THP-1 cells, which exhibited no immediate effect. A direct relationship between frequency-dependent cytotoxicity and mitochondrial superoxide was observed only in Jurkat cells. Jurkat cells were very responsive to NTP in their display of calreticulin and heat shock proteins 70 and 90. In contrast, THP-1 cells were minimally responsive or unresponsive. Despite no NTP-dependent decrease in cell surface display of CD47 in either cell line, both cell types induced migration of and phagocytosis by APCs. Our results demonstrate that cells modulate the RONS-mediated changes in liquid chemistry, and, importantly, the resultant immunomodulatory effects of NTP can be independent of NTP-induced cytotoxicity.

Rate of Onset as a Determinant of Abuse Potential Assessment Using Intracranial Self‐Stimulation in Rats

Background Intracranial self-stimulation (ICSS) is one procedure that has been used to evaluate abuse potential of drugs, and as with more commonly used drug self-administration procedures, ICSS is especially sensitive to drugs that activate the mesolimbic dopamine system. Drug self-administration studies have shown that abuse potential can also be influenced by temporal parameters, and especially rate of onset; however, the degree to which rate of onset influences abuse-potential metrics in ICSS procedures has not been systematically examined. To address this issue, this study evaluated three dopamine transporter (DAT) inhibitors that have different onset rates and were shown previously to maintain different peak break points in rhesus monkeys responding under a progressive-ratio schedule (cocaine > WIN35428 > RTI-31 for both rate of onset and break point). In ICSS, abuse potential is generally indicated when a drug increases low rates of responding maintained by low levels of brain stimulation, a phenomenon called “ICSS facilitation”. We hypothesized that these three DAT inhibitors would facilitate ICSS different time courses, but the degree to which rate of onset might influence peak facilitation was unknown. Methods Adult male and female Sprague-Dawley rats (n = 5-7 per drug) were surgically implanted with permanent stainless-steel electrodes targeting the medial forebrain bundle and trained to respond on a lever to receive electrical brain stimulation. Behavioral sessions were organized in components consisting of ten one-minute frequency trials over a range of brain-stimulation frequencies (56-158 Hz), such that a full curve relating brain-stimulation frequency to response rate could be determined every 10 min. On test days, three baseline ICSS components were followed first by intraperitoneal drug injection and then immediately by 12 consecutive test components (120 min). Additional pairs of test components were initiated at 300 and 1440 minutes post-injection. The drugs and dose ranges tested were as follows: cocaine HCl (1.0 - 10 mg/kg), WIN35428 (0.10 – 0.32 mg/kg), and RTI-31 (0.032 – 0.10 mg/kg). All drugs were tested up to doses that produced peak levels of ICSS facilitation; higher doses disrupted responding and produced stereotypies. Results Under baseline conditions, brain stimulation maintained a frequency-dependent increase in reinforcement rates. All three drugs dose-dependently and robustly facilitated ICSS, shifting ICSS frequency-rate curves to the left and increasing the total number of stimulations per component when data were collapsed across all frequencies. Consistent with previous studies, the rate of onset for ICSS facilitation was fastest for cocaine, slower for WIN35428, and slowest for RTI-31. Cocaine also had the shortest duration of action and the lowest potency, whereas RTI-31 had the longest duration of action and highest potency. However, despite these differences in time course and potency, peak ICSS facilitation was not statistically different across drugs. Conclusions These results suggest that ICSS studies should evaluate rate of onset as well as peak ICSS facilitation in reaching conclusions about overall abuse potential of a test drug.

Resting-state functional EEG connectivity in salience and default mode networks and their relationship to dissociative symptoms during NMDA receptor antagonism

N-methyl-d-aspartate receptor (NMDAR) antagonists administered to healthy humans results in schizophrenia-like symptoms, which are thought in part to be related to glutamatergically altered electrophysiological connectivity in large-scale intrinsic functional brain networks. Here, we examine resting-state source electroencephalographic (EEG) connectivity within and between the default mode (DMN: for self-related cognitive activity) and salience networks (SN: for detection of salient stimuli in internal and external environments) in 21 healthy volunteers administered a subanesthetic dose of the dissociative anesthetic and NMDAR antagonist, ketamine. In addition to provoking symptoms of dissociation, which are thought to originate from an altered sense of self that is common to schizophrenia, ketamine induces frequency-dependent increases and decreases in connectivity within and between DMN and SN. These altered interactive network couplings together with emergent dissociative symptoms tentatively support an NMDAR-hypofunction hypothesis of disturbed electrophysiologic connectivity in schizophrenia.

Responsivity to light in familial hemiplegic migraine type 1 mutant mice reveals frequency-dependent enhancement of visual network excitability.

Migraine patients often report (inter)ictal hypersensitivity to light, but the underlying mechanisms remain an enigma. Both hypo‐ and hyperresponsivity of the visual network have been reported, which may reflect either intra‐individual dynamics of the network or large inter‐individual variation in the measurement of human visual evoked potential data. Therefore, we studied visual system responsivity in freely behaving mice using combined epidural electroencephalography and intracortical multi‐unit activity to reduce variation in recordings and gain insight into visual cortex dynamics. For better clinical translation, we investigated transgenic mice that carry the human pathogenic R192Q missense mutation in the α1A subunit of voltage‐gated CaV2.1 Ca2+ channels leading to enhanced neurotransmission and familial hemiplegic migraine type 1 in patients. Visual evoked potentials were studied in response to visual stimulation paradigms with flashes of light. Following intensity‐dependent visual stimulation, FHM1 mutant mice displayed faster visual evoked potential responses, with lower initial amplitude, followed by less pronounced neuronal suppression compared to wild‐type mice. Similar to what was reported for migraine patients, frequency‐dependent stimulation in mutant mice revealed enhanced photic drive in the EEG beta‐gamma band. The frequency‐dependent increases in visual network responses in mutant mice may reflect the context‐dependent enhancement of visual cortex excitability, which could contribute to our understanding of sensory hypersensitivity in migraine.

Abstract 17038: Influence of Cardiac Workload on Vascular Pyridine Nucleotide Redox State

Introduction: Myocardial perfusion is enhanced during periods of elevated cardiomyocyte oxygen consumption. The coupling between blood flow and myocardial oxygen demand is mediated by redox-dependent signals, yet the influence of cardiac workload on arterial myocyte pyridine nucleotide redox status is unknown. Hypothesis: Increased cardiac workload acutely alters intramyocardial arterial myocyte [NADH] i :[NAD + ] i . Methods and Results: The genetically-encoded fluorescent biosensor Peredox-mCherry was used to monitor real-time changes in intracellular [NADH] i :[NAD] i in isolated arterial myocytes. Treatment of cells expressing Peredox-mCherry with a range of [lactate] o :[pyruvate] o resulted in significant changes in green (Ex,Em: 400, 510 nm): red (Ex,Em: 585,615 nm) fluorescence ratio (1.903 ± 0.010, 10 mM lactate, 1.072 ± 0.073, 10 mM pyruvate), affording accurate quantification of arterial myocyte [NADH] i :[NAD] i . Increased arterial myocyte [NADH] i :[NAD] i was observed in response to reductions in oxygen tension from 5% (0.0021 ± 0.0001) to 1% (0.0050 ± 0.0001; P<0.05). [NADH] i :[NAD] i was not altered by direct stimulation of arterial myocytes with the beta-adrenergic agonist isoproterenol (1 μM; P = .0630). Furthermore, biosensor-expressing arterial myocytes in co-culture with human induced pluripotent stem cell-derived cardiomyocytes (iPSC-CMs) recapitulated the effects of elevated [lactate] o :[pyruvate] o and reduced oxygen tension, exhibiting frequency-dependent increases in [NADH] i :[NAD] I following electrical pacing (e.g., ~3.3 fold increase in 3 Hz vs. unpaced; P<0.05). Consistent with these results, intramyocardial coronary arteries in mice acutely treated with dobutamine (10 mg/kg, i.p.) to drive high cardiac work exhibited significantly greater lactate:pyruvate ratio, used as a surrogate for [NADH] i :[NAD] i , compared with those in hearts treated with vehicle (3.17 ± 0.23 vs. 2.21 ± 0.11; P<0.05). Conclusions: Our results indicate that acute increases in cardiac workload promote the elevation of [NADH] i :[NAD] i in intramyocardial arterial myocytes.

Age-dependent effects of protein restriction on dopamine release

Despite the essential role of protein intake for health and development, very little is known about the impact of protein restriction on neurobiological functions, especially at different stages of the lifespan. The dopamine system is a central actor in the integration of food-related processes and is influenced by physiological state and food-related signals. Moreover, it is highly sensitive to dietary effects during early life periods such as adolescence due to its late maturation. In the present study, we investigated the impact of protein restriction either during adolescence or adulthood on the function of the mesolimbic (nucleus accumbens) and nigrostriatal (dorsal striatum) dopamine pathways using fast-scan cyclic voltammetry in rat brain slices. In the nucleus accumbens, protein restriction in adults increased dopamine release in response to low and high frequency trains of stimulation (1–20 Hz). By contrast, protein restriction during adolescence decreased nucleus accumbens dopamine release. In the dorsal striatum, protein restriction at adulthood has no impact on dopamine release but the same diet during adolescence induced a frequency-dependent increase in stimulated dopamine release. Taken together, our results highlight the sensitivity of the different dopamine pathways to the effect of protein restriction, as well as their vulnerability to deleterious diet effects at different life stages.

Neural Mechanisms Underlying High-Frequency Vestibulocollic Reflexes In Humans And Monkeys.

The vestibulocollic reflex is a compensatory response that stabilizes the head in space. During everyday activities, this stabilizing response is evoked by head movements that typically span frequencies from 0 to 30 Hz. Transient head impacts, however, can elicit head movements with frequency content up to 300-400 Hz, raising the question whether vestibular pathways contribute to head stabilization at such high frequencies. Here, we first established that electrical vestibular stimulation modulates human neck motor unit (MU) activity at sinusoidal frequencies up to 300 Hz, but that sensitivity increases with frequency up to a low-pass cutoff of ∼70-80 Hz. To examine the neural substrates underlying the low-pass dynamics of vestibulocollic reflexes, we then recorded vestibular afferent responses to the same electrical stimuli in monkeys. Vestibular afferents also responded to electrical stimuli up to 300 Hz, but in contrast to MUs their sensitivity increased with frequency up to the afferent resting firing rate (∼100-150 Hz) and at higher frequencies afferents tended to phase-lock to the vestibular stimulus. This latter nonlinearity, however, was not transmitted to neck motoneurons, which instead showed minimal phase-locking that decreased at frequencies >75 Hz. Similar to human data, we validated that monkey muscle activity also exhibited low-pass filtered vestibulocollic reflex dynamics. Together, our results show that neck MUs are activated by high-frequency signals encoded by primary vestibular afferents, but undergo low-pass filtering at intermediate stages in the vestibulocollic reflex. These high-frequency contributions to vestibular-evoked neck muscle responses could stabilize the head during unexpected head transients.SIGNIFICANCE STATEMENT Vestibular-evoked neck muscle responses rely on accurate encoding and transmission of head movement information to stabilize the head in space. Unexpected transient events, such as head impacts, are likely to push the limits of these neural pathways since their high-frequency features (0-300 Hz) extend beyond the frequency bandwidth of head movements experienced during everyday activities (0-30 Hz). Here, we demonstrate that vestibular primary afferents encode high-frequency stimuli through frequency-dependent increases in sensitivity and phase-locking. When transmitted to neck motoneurons, these signals undergo low-pass filtering that limits neck motoneuron phase-locking in response to stimuli >75 Hz. This study provides insight into the neural dynamics producing vestibulocollic reflexes, which may respond to high-frequency transient events to stabilize the head.