Loop Analysis Research Articles

Role of the Egr2 Promoter Antisense RNA in Modulating the Schwann Cell Chromatin Landscape

Background: Schwann cells (SCs) and their plasticity contribute to the peripheral nervous system’s capacity for nerve regeneration after injury. The Egr2/Krox20 promoter antisense RNA (Egr2-AS) recruits chromatin remodeling complexes to inhibit Egr2 transcription following peripheral nerve injury. Methods: RNA-seq and ATAC-seq were performed on control cells, Lenti-GFP-transduced cells, and cells overexpressing Egr2-AS (Lenti-AS). Egr2 AS-RNA was cloned into the pLVX-DsRed-Express2-N1 lentiviral expression vector (Clontech, Mountain View, CA, USA), and the levels of AS-RNA expression were determined. Ezh2 and Wdr5 were immunoprecipitated from rat SCs and RT-qPCR was performed against AS-Egr2 RNA. ChIP followed by DNA purification columns was used to perform qPCR for relevant promoters. Hi-C, HiC-DC+, R, Bioconductor, and TOBIAS were used for significant and differential loop analysis, identifications of COREs and CORE-promotor loops, comparisons of TF activity at promoter sites, and identification of site-specific TF footprints. OnTAD was used to detect TADs, and Juicer was used to identify A/B compartments. Results: Here we show that a Neuregulin-ErbB2/3 signaling axis mediates binding of the Egr2-AS to YY1Ser184 and regulates its expression. Egr2-AS modulates the chromatin accessibility of Schwann cells and interacts with two distinct histone modification complexes. It binds to EZH2 and WDR5 and enables targeting of H3K27me3 and H3K4me3 to promoters of Egr2 and C-JUN, respectively. Expression of the Egr2-AS results in reorganization of the global chromatin landscape and quantitative changes in the loop formation and contact frequency at domain boundaries exhibiting enrichment for AP-1 genes. In addition, the Egr2-AS induces changes in the hierarchical TADs and increases transcription factor binding scores on an inter-TAD loop between a super-enhancer regulatory hub and the promoter of mTOR. Conclusions: Our results show that Neuregulin-ErbB2/3-YY1 regulates the expression of Egr2-AS, which mediates remodeling of the chromatin landscape in Schwann cells.

Assessment of ventricular mechanics by means of myocardial work in patients undergoing physiologic versus right ventricular apical stimulation:a prospective study

Abstract Introduction Left bundle branch area (LBBA) pacing has recently gained widespread acceptance in patients that need pacemaker (PM) stimulation. This type of physiologic pacing may improve ventricular mechanical contraction and reduce the risk of PM-induced left ventricular (LV) dysfunction. Myocardial work (MW), a new tool, based on the analysis of pressure-strain loops, combines the information from speckle tracking strain imaging and non-invasive estimate of LV pressure. It provides a better characterization of LV performance and detection of LV myocardial dysfunction. The aim of this study was to compare MW after PM implantation in LBBA pacing patients (group 1) vs right ventricular apical (RVA, group 2) pacing patients. A control group (group 3) was also enrolled for establishing MW normal values. Methods We studied 30 patients (56% females, age 80 y, IQR 75-84) who underwent PM implantation and had a high probability of a high % of stimulation and 21 controls (57% females, age 79 y, IQR 73-85, p=0.46 and p=0.73 respectively) Patients were prospectively included at two large university hospitals from March 23 until February 24. The mode of stimulation was chosen at their physician’s discretion. Exclusion criteria included LVEF <50% or significant structural or valvular disease. We compared MW parameters between group 1 and group 2 before PM implantation, and 24 hours and 3 months post PM implantation by Kruskal Wallis test. Additionally, we compared MW parameters between group 3 and PM patients after 24 hours using U Mann-Whitney test. Results The % of stimulation was 93%±12. There were no differences in baseline characteristics between group 1 (n=21, 71%) and group 2. At baseline, global work index (GWI), global constructive work (GCW), global wasted work (GWW) or global work efficiency (GWE) did not differ significantly between Group 1 and 2. At 24 hours, all the components of MW significantly improved in Group 1 and 2 and were maintained at 3 months, but the improvement was notably greater in Group 1 (see Table 1). Group 3 and PM patients were similar at baseline (HTN, 86% vs 80%, p=0.7197; DM, 29% vs 30%, p=0.91; coronary artery disease, 14% vs 10%, p=0.68; sinus rhythm, 76% vs 83%, p=0.68). Comparing group 3 and PM at 24 h, GWI, GCW, GWE was significantly higher in group 3 (p=0.0023, p=0.009, p=<0.0001) and GWW was significantly lower (p=<0.0001). Regarding the type of stimulation, MW parameters values in Group 1 were still lower than in Group 3 but clearly better than Group 2 values (see Figure 1). Discussion Our results showed that MW parameters improved to a greater extent in LBBA compared to RVA pacing immediately and after 3 months of PM implantation. Compared to our control group, LBBA pacing group achieved better performance than RVA pacing patients, yielding a more coordinated LV contraction. Nevertheless, more studies are needed to clarify if LBBA pacing causes less PM induced LV dysfunction compared to RVA pacing.

Left ventricular pressure-strain loops for the assessment of myocardial work in a low-risk community-based cohort: associations with long-term prognosis

Abstract Background Non-invasive left ventricular (LV) pressure-strain loop analysis is a novel technique for the evaluation of global myocardial work (GMW) that provides additional insights on LV contractility and energetics beyond traditional metrics, such as ejection fraction (EF) and global longitudinal strain (GLS). Despite its established value in numerous cardiac diseases, there remains limited data on its predictive power in a low-risk population. Purpose Our objective was to determine the long-term prognostic value of GMW in a population-based screening sample comprising low-risk adult individuals. Methods We retrospectively identified 1562 volunteers from a population-based screening program (mean age 54±15 years, 59% female), with a median follow-up time of 11 years. All subjects underwent 2D echocardiography to measure LV EF, GLS, peak atrial longitudinal strain (PALS), GMW index (GMWI), global wasted work (GWW), and GMW efficiency (GMWE). The primary endpoint was all-cause mortality. Results 191 subjects (12,2%) met the primary endpoint. Subjects who experienced adverse outcomes exhibited significantly lower LV EF (dead vs. alive; 49.7±8.3 vs. 52.7 ±6.4 %, p<0.001), GLS (-18.7±4.1 vs. -20.4±3.6 %, p<0.001), PALS (33.6±15.7 vs. 44.2±15.2 %, p<0.001), and GMWI (2181.7±591.3 vs. 2286.8±482.5 mmHg%, p=0.008). Furthermore, subjects with adverse outcomes had significantly higher GWW (132.6±249.4 vs 95.1±113.4 mmHg%, p<0.001) and, consequently, lower GMWE (0.95±0.05 vs. 0.96±0.03, p<0.001). Univariate Cox regression analysis revealed GMWI to be a significant predictor of mortality (hazard ratio for 100 units 0.957 [95% CI: 0.929-0.986], p=0.004), alongside GMWE (hazard ratio for 1 percent 0.940 [95% CI: 0.912-0.968], p<0.001), and GWW (hazard ratio for 100 units 1.124 [95% CI: 1.063-1.188], p<0.001). By multivariable Cox regression encompassing age, sex, GMWI, LVEF, GLS, PALS, and systolic blood pressure, GMWI remained an independent predictor of all-cause mortality (hazard ratio 0.932 [95% CI: 0.874-0.995], p=0.035), while GLS was not an independent predictor. Moreover, integrating the Atherosclerosis Risk in Communities (ARIC)-HF risk factors (age, sex, race, coronary artery disease, antihypertensive medication, blood pressure, diabetes mellitus, body mass index, heart rate, and smoking status), we constructed a multivariate model with GMWI. GMWI was still an independent predictor of mortality (hazard ratio for 100 units 0.941 [95% CI: 0.903-0.980], p=0.004). Using the GMWI cut-off value of 1576 mm Hg% (based on a large-scale healthy population study), the population was divided into 2 groups. Using Kaplan-Meier curves (Figure), the outcomes of the groups differed significantly (log-rank p<0.001). Conclusions GMW provides added value in clinical outcome prediction, even in low-risk individuals. Myocardial work analysis is a promising approach for a comprehensive evaluation of cardiac function and for cardiovascular risk stratification.

The ghrelin receptor agonist AC01 improves cardiac function in non-human primates and in mice with heart failure by increasing cardiomyocyte contractility

Abstract Background Current therapy for Heart Failure (HF) includes neurohormonal antagonist and modulator drugs that improve remodelling, symptoms and clinical outcomes. However, these drugs do not target the underlying problem of reduced contractility. Improving cardiac contractility without harmful consequences is an unmet need in heart failure therapy. The human peptide hormone ghrelin increases cardiac output in HF patients and increases contractility in murine cardiomyocytes. Purpose We aim to study the cardiovascular effects of a novel oral small molecule ghrelin receptor agonist, AC01, in in vivo and ex vivo mouse models and in non-human primates. Methods HF mice (N=11) underwent pressure-volume loops analysis of cardiac functional and hemodynamic to assess the effects of intravenous AC01 (N=7) or placebo (N=4). Primary cardiomyocytes isolated from HF (N=3) and SHAM (N=5) mice, were treated with combinations of vehicle, AC01, ghrelin receptor antagonist (D-Lys-3-GHRP-6) and pertussis toxin (PTX, a Gαi signalling inhibitor). Live cell imaging was performed to assess cardiomyocyte fractional shortening and Ca2+ signalling, while biochemistry assays were employed to measure PKA activity, and phosphorylation of cardiac Troponin I (cTnI). Cynomolgus monkeys (N=6) were instrumented with devices to measure pulse contour, central aortic blood pressure and ECG devices. Cardiovascular effects of AC01 following single oral dosing were assessed through pulse contour hemodynamic modelling and analysis of autonomic system activation. Results In HF mice, AC01 significantly improved cardiac output (p< 0.01), stroke volume (p< 0.001), and ejection fraction (p< 0.001), and increased nominally the end-systolic pressure-volume curve relationship. In cardiomyocytes, AC01 dose-dependently improved fractional shortening (p< 0.01) without increasing Ca2+ transient amplitudes. AC01 reduced PKA activity (p< 0.05) and reduced phosphorylation of cTnI at Serine 23-24 (p< 0.01). These effects were blocked by pre-treatment with either D-Lys-3-GHRP-6 or PTX. In monkeys, oral AC01 sustainably increased cardiac output (p< 0.05) and stroke volume (p< 0.05) and reduced heart rate without altering central systolic blood pressure or causing tachycardia or arrhythmia. Conclusions AC01 improved CO, SV, and EF in HF mice by increasing contractility in a load-independent fashion. AC01 increased cardiomyocyte contractility without affecting Ca2+ transient amplitudes, through ghrelin receptor Gαi signalling, leading to reduced phosphorylation of cTnI. AC01 improved left ventricle systolic function in monkeys. AC01 is a first in class novel inotrope, which improves contractility in different species without harmful mobilization of Ca2+. AC01 should be explored for the treatment of patients with heart failure.graphical abstract

Investigating the Role of Hub Calcification Proteins in Atherosclerosis via Integrated Transcriptomics and Network-Based Approach

Atherosclerosis (AS) is a chronic inflammatory condition of the arteries, characterized by plaque formation that can restrict blood flow and lead to potentially fatal cardiovascular events. Given that AS is responsible for a quarter of global deaths, this study aimed to develop a systematic bioinformatics approach to identify biomarkers and regulatory targets involved in plaque development, with the goal of reducing cardiovascular disease risk. AS-specific mRNA expression profiles were retrieved from a publicly accessible database, followed by differentially expressed genes (DEGs) identification and AS-specific weighted gene co-expression network (WGCN) construction. Thereafter, calcification and atherosclerosis-specific (CASS) DEGs were utilized for protein–protein interaction network (PPIN) formation, followed by gene ontology (GO) term and pathway enrichment analyses. Lastly, AS-specific 3-node miRNA feed-forward loop (FFL) construction and analysis was performed. Microarray datasets GSE43292 and GSE28829 were obtained from gene expression omnibus (GEO). A total of 3785 and 6176 DEGs were obtained in case of GSE28829 and GSE43292; 3256 and 5962 module DEGs corresponding to GSE28829 and GSE43292 were obtained from WGCN. From a total of 54 vascular calcification (VC) genes, 20 and 29 CASS-DEGs corresponding to GSE28829 and GSE43292 were overlapped. As observed from FFL centrality measures, the highest-order subnetwork motif comprised one TF (SOX7), one miRNA (miR-484), and one mRNA (SPARC) in the case of GSE28829. Also, in the case of GSE43292, the highest-order subnetwork motif comprised one TF (ESR2), one miRNA (miR-214-3p), and one mRNA (MEF2C). These findings have important implications for developing new therapeutic strategies for AS. The identified TFs and miRNAs may serve as potential therapeutic targets for treating atherosclerotic plaques, offering insights into the molecular mechanisms underlying the pathogenesis and highlighting new avenues for research and treatment.

Loop analysis quantifying important species in a marine food web

Improving the predictive power of food web analysis is a major challenge. Identifying the relationships that link topological and dynamical features may help. We used the predictions of loop analysis about the effect of perturbations targeted to the components of Barents sea food web to quantify their sensitivity and community impact, that we summarized in two new indices, NI and NS. Using a multivariate analysis we interpreted the meaning of these indices in a benchmarking exercise using several well recognized indices of species topological (positional) importance. Our findings suggest that the information the two indices proposed here provides does not overlap with that of more diffused topological indices of positional importance (i.e. centrality indices). The former are express the dynamic consequences of the topology in which species are embedded, whereas for the latter such dynamical consequences are mostly hypothesized on a topological base. The indices of loop analysis are based on the effective role a species plays in passing the impacts to other species (NI) and their role as sinks of the perturbations entering anywhere in the system (NS). These two indices, in the end, reveal how the topology of the network affects the response of the species to perturbations and thus emphasize the interaction between topology and dynamics. Based on our results, the question related to conservation is whether to prioritize sensitive species, that can be more strongly influenced when others are perturbed, or species of high impact, that can more strongly influence the rest of the community if perturbed.

Sacubitril/Valsartan Combination Partially Improves Cardiac Systolic, but Not Diastolic, Function through β-AR Responsiveness in a Rat Model of Type 2 Diabetes

Cardiovascular complications are the major cause of diabetes mellitus-related morbidity and mortality. Increased renin–angiotensin–aldosterone system activity and decreased β-adrenergic receptor (β-AR) responsiveness contribute to diabetic cardiac dysfunction. We evaluated the effect of sacubitril/valsartan (neprilysin inhibitor plus angiotensin receptor antagonist combination) and valsartan treatments on the diabetic cardiac function through β-AR responsiveness and on protein expression of diastolic components. Six-week-old male Sprague Dawley rats were divided into control, diabetic, sacubitril/valsartan (68 mg/kg)-, and valsartan-treated (31 mg/kg) diabetic groups. Diabetes was induced by a high-fat diet plus low-dose streptozotocin (30 mg/kg, intraperitoneal). After 10 weeks of diabetes, rats were treated for 4 weeks. Systolic/diastolic function was assessed by in vivo echocardiography and pressure–volume loop analysis. β-AR-mediated responsiveness was assessed by in vitro papillary muscle and Langendorff heart experiments. Protein expression of sarcoplasmic reticulum calcium ATPase2a, phospholamban, and phosphorylated phospholamban was determined by Western blot. Sacubitril/valsartan improved ejection fraction and fractional shortening to a similar extent as valsartan alone. None of the treatments affected in vivo diastolic parameters or the expression of related proteins. β1-/β2-AR-mediated responsiveness was partially restored in treated animals. β3-AR-mediated cardiac relaxation (an indicator of diastolic function) responses were comparable among groups. The beneficial effect of sacubitril/valsartan on systolic function may be attributed to improved β1-/β2-AR responsiveness.

The magnetic characteristics of spinel-type MnCo2O4 at low temperatures

We report the magnetic properties of spinel oxide MnCo2O4 at low temperatures which is prepared through the sol-gel reaction process. The XPS results suggest that Mn3+ atoms exist in the octahedral sublattice originally occupied by Co3+ atoms. Afterwards, the AC susceptibility was measured at various frequencies, confirming a spin glass behavior at low temperatures. Additionally, analysis of the hysteresis loops revealed the presence of the exchange bias effect in our sample. The coexistence of spin glass behavior and the exchange bias effect in MnCo2O4 is attributed to the competition between ferromagnetic and antiferromagnetic interaction. The disorders of magnetic atoms in the lattice will also provide synergy for these magnetic behaviors.

Deep phenotyping of unaffected carriers of pathogenic BMPR2 variants screened for pulmonary arterial hypertension.

Pathogenic variants in the gene encoding for BMPR2 are a major genetic risk factor for heritable pulmonary arterial hypertension. Owing to incomplete penetrance, deep phenotyping of unaffected carriers of a pathogenic BMPR2 variant through multimodality screening may aid in early diagnosis and identify susceptibility traits for future development of pulmonary arterial hypertension. 28 unaffected carriers (44±16 years, 57% female) and 21 healthy controls (44±18 years, 48% female) underwent annual screening, including cardiac magnetic resonance imaging, transthoracic echocardiography, cardiopulmonary exercise testing and right heart catheterisation. Right ventricular pressure-volume loops were constructed to assess load-independent contractility and compared with a healthy control group. A transgenic Bmpr2Δ71Ex1/+ rat model was employed to validate findings from humans. Unaffected carriers had lower indexed right ventricular end-diastolic (79.5±17.6 mL·m-2 versus 62.7±15.3 mL·m-2; p=0.001), end-systolic (34.2±10.5 mL·m-2 versus 27.1±8.3 mL·m-2; p=0.014) and left ventricular end-diastolic (68.9±14.1 mL·m-2 versus 58.5±10.7 mL·m-2; p=0.007) volumes than control subjects. Bmpr2Δ71Ex1/+ rats were also observed to have smaller cardiac volumes than wild-type rats. Pressure-volume loop analysis showed that unaffected carriers had significantly higher afterload (arterial elastance 0.15±0.06 versus 0.27±0.08 mmHg·mL-1; p<0.001) and end-systolic elastance (0.28±0.07 versus 0.35±0.10 mmHg·mL-1; p=0.047) in addition to lower right ventricular pulmonary artery coupling (end-systolic elastance/arterial elastance 2.24±1.03 versus 1.36±0.37; p=0.006). During the 4-year follow-up period, two unaffected carriers developed pulmonary arterial hypertension, with normal N-terminal pro-brain natriuretic peptide and transthoracic echocardiography indices at diagnosis. Unaffected BMPR2 mutation carriers have an altered cardiac phenotype mimicked in Bmpr2Δ71Ex1/+ transgenic rats. Future efforts to establish an effective screening protocol for individuals at risk for developing pulmonary arterial hypertension warrant longer follow-up periods.

Tetrapyrrolic macrocycles self-organization into floating layers and sensory properties of their Langmuir-Schaefer films

The influence of the chemical structure of the 5,10,15,20-tetraphenylporphyrin (I) and 2-aza-21-carba-5,10,15,20-tetraphenylporphyrin (II) on their supramolecular organization in floating layers at the air/water interface and sensor properties in Langmuir-Schaefer films has been investigated. It was shown that a minor change in the macrocycle structure (namely, the replacement of a single nitrogen atom from the center to the periphery of macrocycle) has a considerable effect on the surface properties and hysteresis processes of the floating layers. Using the Bruster angle microscopy, it was established that both porphyrins aggregate even before the compression of their floating layers begins. The aggregation is more pronounced in porphyrin I. The analysis of hysteresis loops showed that the formation of a floating layer by the modified porphyrin II requires approximately 100 times more energy than for the unmodified porphyrin I. Using the Langmuir-Schaefer (LS) method, the floating layers were transferred onto solid substrates and the resulting thin films were analyzed by atomic force microscopy, scanning electron microscopy, polarization optical microscopy, and spectrophotometry. The combination of these methods revealed a general tendency of the porphyrins to form 3D structures on the surface of LS-films. The study of the basic properties of the porphyrin's LS-films showed that both porphyrins are diprotonated. The protonation process in porphyrin II occurs at a concentration of HClO4 that is 1000 times lower than that observed in porphyrin I. The greater tendency to protonation of porphyrin II is caused by the availability of both nitrogen atoms (the external nitrogen atom located at the macrocycle periphery and the internal nitrogen atom, which becomes more assesible to interactions due to the distortion of the macrocycle). As for the sensor properties of LS-films for iodide ion in aqueous solutions, it was observed that the diprotonated form of porphyrin I exhibited higher sensitivity due to a more developed film surface because of the presence of a greater number of 3D aggregates. The data obtained can be used in the development of efficient pH-controlled thin-film sensor materials for halide ions.

Tidal Breathing Analysis as a Prognostic Index for Airway Obstruction Trajectory and Asthma in Preterm Infants.

An easy-to-implement and accurate lung function assessment tool for preterm infants is crucial to manage lifelong respiratory morbidities. We aimed to determine which pulmonary function parameters in preterm infants can predict the trajectory of airway obstruction and asthma development after 4years of age. We evaluated 52 preterm infants who had undergone both tidal breathing flow-volume loop (TBFVL) and multiple-breath washout (MBW) analyses in infancy and spirometry after the age of 4years. We evaluated the association between pulmonary function parameters in infancy and childhood and the pulmonary function trajectory until 13years of age and compared the changes in this trajectory according to pulmonary function parameters in infancy. Time to peak expiratory flow/expiratory time (TPEF/TE) in infancy was associated with FEV1, FEF25-75, and dysanapsis ratio in childhood and differed according to level of airway obstruction assessed by FEV1, FEV1/FVC, and FEF25-75, an asthma development. TPEF/TE was a significant predictive factor for airway obstruction and asthma after 4years of age, after adjusting for sex, extreme prematurity, duration of supplementary oxygen and mechanical ventilation, and recurrent wheezing during infancy. In premature infants with lower TPEF/TE, subsequent pulmonary function parameters remained low until 13years of age. In preterm infants, TPEF/TE could be useful to predict airway obstruction and asthma after 4years of age and even a lower pulmonary function trajectory until 13years of age. This information may help clinicians to provide lifelong care for pulmonary morbidity in children and adolescents born preterm.

Cr–Sc co-substituted nickel-cobalt nanospinel ferrites: An investigation of their structural, magnetic properties and hyperfine interactions

The chromium and scandium co-substituted nickel-cobalt nanospinel ferrites (NSFs) having general formula of Co0.5Ni0.5ScxCrxFe2-2xO4 (CoNiScCr) (x ≤ 0.10) have been fabricated through the sol-gel route and citric acid as fuel and characterized by X-ray diffractometry (XRD), 57Fe Mössbauer spectroscopy, vibrating sample magnetometry (VSM), and finally by scanning and transmission electron microscopy techniques (SEM and TEM, respectively). The crystallite size (Dmax) values of the products were estimated to lay between 31 and 46 nm, which was calculated by the Scherrer formula. It was observed that the doping ions’ concentration did not have a linear impact on the expansion of the lattice constant. SEM and TEM present the cubic shape of CoNiScCr NSFs. All ratios demonstrate highly agglomerated cubic particles with diverse sizes. Both XRD and EDX (Energy Dispersive X-ray Spectroscopy) analyses confirmed the absence of any impurity/phases. Through an analysis of hysteresis loops at 300 (RT = room temperature) and 20 K, along with a probe of temperature-induced alteration in magnetization M, the magnetic properties of CoNiScCr (x ≤ 0.10) NSFs have been thoroughly investigated. Notably, all products exhibited complementary soft and hard magnetic behaviors at RT and 20 K, respectively. At 20 K, the observation of squareness ratio values surpassing 0.5 exhibits a single-domain behavior at this specific temperature. Magnetic parameters, in general, exhibit fluctuations with increasing doping content. Across the entire range of materials studied, a notable trend emerges as the temperature decreases, the magnetization in the zero field cooling curves shows a non-linear decrease, eventually stabilizing in the field cooling branches. The findings suggest that the inclusion of Sc3+/Cr3+ dopants can be utilized to manipulate and achieve desired magnetic properties in Co–Ni ferrites. The spectra of Mössbauer analysis, which was utilized to establish the distribution of cations, presented four magnetic sextets for all samples. Doped ions are substituted with Fe3+ ions at the B site.

Unveiling the potential of a novel inorganic perovskite for NTC thermistor and energy-storage applications

Inorganic perovskite-oriented materials are renowned for their multifunctional characteristics, making them candidates for various advanced applications. This study focuses on the synthesis and characterization of a novel inorganic perovskite material, (Ni0.5Sm0.5FeO3)0.5(BaTiO3)0.5, prepared via the cost-effective solid-state reaction method. Detailed structural and microstructural analyses were conducted to determine phase formation and grain size effects. Rietveld analysis was employed to identify the crystallographic phases, while field emission scanning electron microscopy (FE-SEM) provided insights into the sample’s morphology. FTIR and RAMAN spectroscopy were used to investigate the vibrational modes of the material. The dielectric properties and electrical characteristics were measured across a range of frequencies and temperatures using an impedance analyzer. The material’s potential for energy storage and NTC-type thermistor applications was evaluated through its temperature coefficient of resistance (TCR) and thermistor constant (β) analysis. Additionally, the ferromagnetic property was assessed through M−H hysteresis loop analysis, highlighting the material’s multifunctional capabilities.

Investigating phase and magnetic properties in Co-2 wt.% MWCNT nano-composites prepared by mechanical alloying

MWCNT nano-composites with a cobalt content of 2 weight percent were created by mechanically alloying during different times. Modern techniques, including x-ray diffraction (XRD), differential thermal analysis (DTA), field emission scanning electron microscopy (FESEM), high-resolution transmission electron microscopy (HRTEM) and superconducting quantum interference device (SQUID), were used to examine the effects of CNT addition on the Co morphology and magnetic characteristics of the samples. It was shown that the characteristics of Co in 2 weight percent MWCNT nano-composites were retained in a sample that was milled for 60 min. Agglomerates of nanoparticles were the end result, with CNTs evenly distributed throughout the cobalt matrix 60 min after mechanical alloying. Analysis of magnetic hysteresis loops revealed that the inclusion of CNTs altered the magnetic characteristics of nano-composite samples. Analysis of magnetic hysteresis loops revealed that the inclusion of CNTs altered the magnetic characteristics of nano-composite samples. The well-developed interfacial structure in this work significantly improved the cobalt-MWCNT nano-composites’ magnetic characteristics.

Intraoperative right ventricular end-systolic pressure–volume loop analysis in patients undergoing cardiac surgery: A proof-of-concept methodology

BackgroundPerioperative right ventricular (RV) dysfunction is associated with increased morbidity and mortality in cardiac surgery patients. This study aimed to demonstrate proof of concept in generating intraoperative RV pressure–volume (PV) loops and conducting an end-systolic PV relationship (ESPVR) analysis using data obtained from routinely used intraoperative monitors. MethodsAdult patients undergoing cardiac surgery with the placement of a pulmonary artery catheter (PAC) between May 2023 and March 2024 were included prospectively. The PV loops were generated using 3-dimensional echocardiographic RV volume data and continuous RV pressure data obtained from a PAC. The volume–time and pressure–time curves were digitized using the semiautomatic WebPlotDigitizer program and synchronized to reconstruct an RV PV loop and analyze ESPVR using the previously validated single-beat method. ResultsIntraoperative RV PV loops were generated for 25 patients, including 17 patients with preserved RV systolic function (group 1) and 8 patients with reduced systolic function (group 2). Mean Ees, Ea, and Ees/Ea ratio were 0.63 ± 0.25 mm Hg/mL, 0.60 ± 0.23 mm Hg/mL, and 1.0 8 ± 0.31 mm Hg/mL, respectively, by the Pmax method and 0.56 ± 0.32 mm Hg/mL, 0.60 ± 0.23 mm Hg/mL, and 0.91 ± 0.21 mm Hg/mL, respectively, by the V0 method. Group 1 had a significantly higher Ees compared to group 2 regardless of the calculation method and a larger Ees/Ea ratio calculated by the V0 method. ConclusionsIt is clinically feasible to derive RV PV loops from routine hemodynamic and echocardiographic data. With further validation and technological support, this can be a potential real-time intraoperative RV function monitoring tool.

The structural, magnetic and electrical properties of chromium doped calcium ferrite nanoparticles

Calcium ferrite nanoparticles doped with Chromium (10-50 mol %) are synthesized using the solution combustion method, employing citrus Lemon extract as a reducing agent, followed by a calcination process at 500oC. Various characterization techniques are employed on the calcined samples. The Bragg reflections resulting from Chromium doping confirm the formation of a singular orthorhombic calcium ferrite phase. Crystallite sizes determined using both Scherrer’s and W-H plot methods found to be decreases with increase in dopant concentration. The surface morphology showcases agglomerated nanoparticles with irregular shapes and sizes, accompanied by pores and voids. The energy band gap found to be increases with increase in dopant concentration from 2.82 to 2.93 eV. The hysteresis loop analysis provides magnetic parameters including saturation magnetization (Ms), remanence (Mr), and coercivity (Hc). As the dopant concentration increases, Ms and Hc found to be maximum at 30 mol% cr3+ concentration in CaFe2O4 NPs. Linear increase in frequency-dependent conductivity at lower frequencies was observed. The presence of semicircles at low frequencies signifies compliance with the Cole-Cole formula for impedance behavior. Additionally, a detailed discussion on dielectric properties is presented. Notably, the dielectric constant decreases from 4.2 to 2.74 with an increase in dopant concentration. These distinctive attributes position the samples as suitable candidates for memory devices as well as high-frequency device applications.

Analysis of hysteresis loops and dielectric performance in the ovalene-like system: Monte Carlo study

This Monte Carlo study offers a comprehensive analysis of the ovalene-like system, emphasizing its dielectric behavior, thermal performance and hysteresis loops. The investigation reveals intricate dynamics influenced by diverse parameters, contributing to a nuanced understanding of the system’s response. Additionally, the study scrutinizes the impact of various physical parameters on the thermal behavior of polarizations and susceptibilities. The examination thoroughly explores the influence of these parameters on loop characteristics, coercive field, and saturation behavior, unveiling the formation of multiple loops and polarization plateaus on the electric hysteresis. In summary, this study advances our understanding of the ovalene-like system’s dielectric response, thermal characteristics and hysteresis dynamics, providing valuable insights for future research and applications, particularly in advanced electronic devices.

Low Ventricular Stiffness Is Associated With Suboptimal Outcomes in Patients With a Single Right Ventricle After the Fontan Operation: A Novel Phenotype.

Despite a rigorous screening process, including cardiac catheterization, a subset of patients with a single right ventricle (SRV) demonstrates suboptimal short-term outcomes after the Fontan operation. The goal of this study was to perform a comprehensive assessment of diastolic function in pre-Fontan patients with an SRV using invasive reference-standard measures and determine their associations with post-Fontan outcomes. Children aged 2 to 6 years with SRV physiology undergoing pre-Fontan heart catheterization were recruited prospectively. Patients were divided into those who had an optimal or suboptimal outcome. A suboptimal outcome was defined as length of stay ≥14 days or heart transplant/cardiac death in first year after Fontan. Patients underwent pressure-volume loop analysis using reference-standard methods. The measure of ventricular stiffness, β, was obtained via preload reduction. Cardiac magnetic resonance imaging for extracellular volume and serum draws for matrix metalloproteinase activity were performed. Of 19 patients with an SRV, 9 (47%) had a suboptimal outcome. Mean age was 4.2±0.7 years. Patients with suboptimal outcomes had lower ventricular stiffness (0.021 [0.009-0.049] versus 0.090 [0.031-0.118] mL-1; P=0.02), lower extracellular volume (25% [28%-32%] versus 31% [28%-33%]; P=0.02), and lower matrix metalloproteinase-2 (90 [79-104] versus 108 [79-128] ng/mL; P=0.01) compared with patients with optimal outcomes. The only invasive measure that had an association with suboptimal outcome was β (P=0.038). Patients with an SRV with suboptimal outcome after the Fontan operation had lower ventricular stiffness and evidence of maladaptive extracellular matrix metabolism compared with patients with optimal outcome. This appears to be a novel phenotype that may have important clinical implications and requires further study.

Artificial neural network aided unstable combustion state prediction and dominant chemical kinetic analysis

An ANN model was designed to predict unstable states in MILD combustion systems out of six kinds of input factors. The effectiveness of the established ANN model was validated, demonstrating accurate predictions for the imbalanced classification problem in systems described by both GRI3.0 and POLIMI2003 mechanisms. The predictions in high-dimensional parameter spaces revealed that unstable states are more likely to occur under stoichiometric conditions or in the presence of a reactive bath gas, such as CO2 or H2O. Additionally, these states could manifest in narrow parameter spaces, such as within a very confined mid-temperature range in a fuel-rich system with a low dilution level. Interestingly, the analysis of dominant reactions and feedback loops unveiled similarities in thermodynamic feedback mechanisms across a spectrum of parameter combinations. Meanwhile, feedback loops construct shortcut pathways on the level of oxidation extent and can facilitate the switching between high and low temperature chemistry.

Development of enhanced force models to analyze the nonlinear hysteresis response of miniaturized pneumatic artificial muscles

Miniaturized pneumatic artificial muscles (MPAMs), designed to replicate natural muscle actuation, offer unique attributes such as a high power-to-weight ratio, flexibility, easy integration, and compactness, making them favourable for many applications. The present paper aims at the development of an accurate semi-analytical force model considering the effect of the bladder material and friction terms to predict the nonlinear force-deformation response of MPAMs during contraction and expansion cycles. Existing force models for MPAMs exhibit limitations to accurately capturing the force-deformation behaviours due to several simplification factors. This study enhances these models by integrating correction terms to accurately address the nonlinearity and frictional effects exhibited by MPAMs. An analysis of the hysteresis loops resulting from the cyclic loading and unloading of MPAMs under specific pressures is undertaken to compare different methodologies in order to determine the most accurate correction terms. To investigate the nonlinear behaviour of MPAMs, the stress-strain relationship of the bladder material and results from force-deformation experimental tests on the entire actuator are considered and for the effect of friction term, theoretical and empirical approaches are investigated. Results suggest that the theoretical force model based on analytical and empirical friction forces, respectively, slightly overestimates and underestimates the force experienced by MPAMs during contraction while slightly underestimate and overestimates during expansion, respectively. A comparative analysis between MPAMs featuring Ecoflex-50 silicone and Ecoflex30 + PDMS mixture as bladder materials has also been conducted to further investigate the effect of bladder materials on their force and contraction outputs under inlet pressures ranging from 0 kPa to 300 kPa. It is shown that the MPAM feauting Ecoflex-50 bladder, exhibits lower dead-band pressure and an overall reduced blocked force in comparison to MPAM with bladder made of Ecoflex30 + PDMS while exhibiting a substantially enhanced free contraction capacity.