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Enlarged perivascular spaces (EPVS) are MRI markers of impaired glymphatic clearance and have been associated with neurodegenerative diseases. However, their clinical significance in amyotrophic lateral sclerosis (ALS) and underlying mechanisms remain poorly understood. This study investigated the prevalence, clinical relevance, and pathophysiological basis of EPVS in ALS. MRI data from 114 ALS patients and 119 matched controls were analyzed, with high-degree EPVS defined as more than 20 visible spaces. High-degree EPVS in the centrum semiovale (CSO) was more prevalent in ALS patients (49.1%) than in controls (15.1%, p < 0.001). Age, male sex, and ALS diagnosis were independent predictors, while disease severity and aggressiveness were not associated. ALS patients with high-degree CSO-EPVS were older at disease onset and MRI but showed similar clinical progression. In SOD1/G93A ALS mice, cerebral perivascular spaces were significantly enlarged at 5 months compared to wild-type and younger ALS mice. Cervical lymphatic ligation promoted misfolded SOD1 accumulation in motor neurons and cerebral vessels, further increasing perivascular space width without altering motor function. These findings suggest that about half of ALS patients exhibit high-degree CSO-EPVS, reflecting impaired protein clearance rather than disease aggressiveness.

Background: Delayed migration and exposure of embolic coils is a rare complication of endovascular therapy for carotid blowout syndrome.Methods: A 64-year-old man with recurrent tongue cancer noticed the presence of foreign body in the malignant wound on the right side of his neck. He had undergone transarterial embolization on his right vertebral artery, right common carotid artery (CCA), and internal carotid artery (ICA) for carotid blowout syndrome 1 month prior. On physical examination, exposed spring-like metallic coils were observed, covered in brownish granulation tissue, at the bottom of the malignant wound. Neck radiograph and computed tomography confirmed the extrusion and migration of the embolic coils.Results: In this case, the patient was managed by transection of the exposed coils at the wound surface with close monitoring.Conclusions: Computed tomography angiography is essential for assessing the condition of the remaining embolic coils. In cases with thrombosed parent arteries, a conservative approach, like the transection of exposed coils, can be employed as part of the management strategy.

Primary aldosteronism is associated with various types of cardiovascular and cerebrovascular damage independently of hypertension. Although chronic hypertension and related cerebral arteriosclerosis are the main risk factors for intracerebral hemorrhage, the effects of aldosteronism remain poorly understood. We enrolled 90 survivors of hypertensive intracerebral hemorrhage, 21 of them with aldosteronism and 69 with essential hypertension as controls in this study. Clinical parameters and neuroimaging markers of cerebral small vessel disease were recorded, and its correlations with aldosteronism were investigated. Our results showed that the aldosteronism group (55.2 ± 9.7 years, male 47.6%) had similar hypertension severity but exhibited a higher cerebral microbleed count (interquartile range) (8.5 [2.0‒25.8] vs 3 [1.0‒6.0], P = 0.005) and higher severity of dilated perivascular space in the basal ganglia (severe perivascular space [number >20], 52.4% vs. 24.6%, P = 0.029; large perivascular space [>3 mm], 52.4% vs. 20.3%, P = 0.010), compared to those with essential hypertension (53.8 ± 11.7 years, male 73.9%). In multivariate models, aldosteronism remained an independent predictor of a higher (>10) microbleed count (odds ratio = 8.60, P = 0.004), severe perivascular space (odds ratio = 4.00, P = 0.038); the aldosterone-to-renin ratio was associated with dilated perivascular space (P = 0.043) and large perivascular space (P = 0.008). In conclusions, survivors of intracerebral hemorrhage with aldosteronism showed a tendency towards more severe hypertensive arteriopathy than the essential hypertension counterparts independently of blood pressure; aldosteronism may contribute to dilated perivascular space around the deep perforating arteries. Aldosteronism is associated with more severe cerebral small vessel disease in hypertensive intracerebral hemorrhage.

Autonomous cortisol secretion (ACS) is not uncommon in patients with primary aldosteronism (PA). However, the cardiovascular burden of ACS due to its dysregulated cortisol secretion remains poorly understood. Thus, we examined the effects of ACS on vascular calcification in a hyperaldosteronism environment in vitro and in vivo. A total of 339 patients with PA with adrenal incidentaloma and low-dose dexamethasone suppression test data (cutoff level: cortisol > 1.8 μg/dL) from a prospectively maintained database were enrolled; abdominal aortic calcification (AAC) scores were quantitatively estimated. Human aortic smooth muscle cells (HAOSMCs) were used as in vitro model of vascular calcification. In this study, 65 of the 339 patients with PA had ACS; 274 did not. Patients with PA/ACS had a higher AAC score (1171.0 ± 2434.0 vs. 489.5 ± 1085.3, P  = 0.012) than patients without ACS. ACS was independently associated with AAC score ( β  = 0.139, P  = 0.004) in multivariate analysis, and post-suppression cortisol level was significantly correlated with the AAC score ( P  = 0.004). In the HAOSMC model, co-treatment with cortisol synergistically stimulated alkaline phosphatase activity and calcium deposition in a hyperaldosteronism environment. The stimulatory effect of cortisol was abolished by the mineralocorticoid receptor (MR) antagonist eplerenone, but not glucocorticoid receptor antagonist mifepristone, indicating a MR-dependent mechanism. In conclusion, the presence of ACS is associated with heavier vascular calcification in patients with PA. Aldosterone and cortisol synergistically activate HAOSMC calcification via MR signaling, via a process that can be attenuated by eplerenone.

[Objective]The purpose of this research is to analyze the coupling between gully,collapse,platform and other micro-topography with spatial distribution of exising forest stand,which can provide references for near-natural vegetation restoration and the structure configuration of soil and water conservation tree-shrub mixed stand. [Method]Based on the investigaition data of the vegetations in Sandaochuan valley in Wuqi County of Shaanxi Province,the effects of slope micro- topography on spatial distribution of trees were analysed by using spatial analysis tools of software Arcgis 9. 3. [Result]The results showed that the area of all types of micro-topography account for 21. 03%in undisturbed slope area,but the amount of trees on micro-topography account for 51. 77% of the total amount.Trees were distributed mainly in various type of micro-topography,and showed an aggregated distribution at gully and platform,but showed a random distribution at collapse and scrap. The trees in different micro-topography display

A novel hydrido iridium chloride complex supported by a tetradentate PNCP ligand has been synthesized and characterized. Upon activation with NaOtBu, the PNCP-IrHC1 complex is active for transfer dehydrogenation of cyclic and linear alkanes.

A series of novel wide bandgap small molecules （IFT-ECA, IFT-M, IFT-TH and IFT-IC） based on the A-D-A structure with indenofluorene core, thiophene bridge, and different electron-deficient end-capping groups, were synthesized and used as non-fullerene acceptors in organic solar cells. The influences of end-capping groups on the device performance were studied. The four materials exhibited different physical and chemical properties due to the variation of end-capping groups, which further affect the exciton dissociation, charge transport, morphology of the bulk-heterojunction films and device performance. Among them, IFT-IC-based device delivered the best power conversion efficiency of 7.16% due to proper nano-scale phase separation morphology and high electron mobility, while the devices based on the other acceptors achieved lower device performance （4.14% for IFT-TH, 〈1% for IFT-ECA and IFT-M）. Our results indicate the importance of choosing suitable electron-withdrawing groups to construct high-performance non-fullerene acceptors based on A-D-A motif.

Over the long history of evolution, nature has developed a variety of biological systems with switchable recognition functions, such as the ion transmissibility of biological membranes, which can switch their ion selectivities in response to diverse stimuli. However, developing a method in an artificial host-guest system for switchable recognition of specific guests upon the change of external stimuli is a fundamental challenge in chemistry because the order in the host-guest affinity of a given system hardly varies along with environmental conditions. Herein, we report temperature-responsive recognition of two similar gaseous guests, CO 2 and C 2 H 2 , with selectivities switched by temperature change by a diffusion-regulatory mechanism, which is realized by a dynamic porous crystal featuring ultrasmall pore apertures with flip-flop locally-motive organic moiety. The dynamic local motion regulates the diffusion process of CO 2 and C 2 H 2 and amplifies their rate differences, allowing the crystal to selectively adsorb CO 2 at low temperatures and C 2 H 2 at high temperatures with separation factors of 498 (CO 2 /C 2 H 2 ) and 181 (C 2 H 2 /CO 2 ), respectively. The design of host-guest systems for switchable recognition of guests upon the change of external stimuli is challenging due to the invariable host-guest affinity. Here, the authors encode a dynamic motion into a porous crystal to regulate the diffusion of CO2 and C2H2 allowing the crystal to switch the gas recognition selectivity by temperature.

Since the origin of life, temperatures on earth have fluctuated both on short and long time scales. How such changes affect the rate at which Darwinian evolution can bring forth new phenotypes remains unclear. On the one hand, high temperature may accelerate phenotypic evolution because it accelerates most biological processes. On the other hand, it may slow phenotypic evolution, because proteins are usually less stable at high temperatures and therefore less evolvable. Here, to test these hypotheses experimentally, we evolved a green fluorescent protein in E. coli towards the new phenotype of yellow fluorescence at different temperatures. Yellow fluorescence evolved most slowly at high temperature and most rapidly at low temperature, in contradiction to the first hypothesis. Using high-throughput population sequencing, protein engineering, and biochemical assays, we determined that this is due to the protein-destabilizing effect of neofunctionalizing mutations. Destabilization is highly detrimental at high temperature, where neofunctionalizing mutations cannot be tolerated. Their detrimental effects can be mitigated through excess stability at low temperature, leading to accelerated adaptive evolution. By modifying protein folding stability, temperature alters the accessibility of mutational paths towards high-fitness genotypes. Our observations have broad implications for our understanding of how temperature changes affect evolutionary adaptations and innovations. The effect of temperature fluctuations on the evolution of new phenotypes is largely unknown. Using experimental evolution of fluorescent protein in E. coli , this study shows that a cooling environment can accelerate, and a warming environment decelerate, the evolution of a new protein phenotype.

The deep sea remains the largest unknown territory on Earth because it is so difficult to explore 1 – 4 . Owing to the extremely high pressure in the deep sea, rigid vessels 5 – 7 and pressure-compensation systems 8 – 10 are typically required to protect mechatronic systems. However, deep-sea creatures that lack bulky or heavy pressure-tolerant systems can thrive at extreme depths 11 – 17 . Here, inspired by the structure of a deep-sea snailfish 15 , we develop an untethered soft robot for deep-sea exploration, with onboard power, control and actuation protected from pressure by integrating electronics in a silicone matrix. This self-powered robot eliminates the requirement for any rigid vessel. To reduce shear stress at the interfaces between electronic components, we decentralize the electronics by increasing the distance between components or separating them from the printed circuit board. Careful design of the dielectric elastomer material used for the robot’s flapping fins allowed the robot to be actuated successfully in a field test in the Mariana Trench down to a depth of 10,900 metres and to swim freely in the South China Sea at a depth of 3,224 metres. We validate the pressure resilience of the electronic components and soft actuators through systematic experiments and theoretical analyses. Our work highlights the potential of designing soft, lightweight devices for use in extreme conditions. A free-swimming soft robot inspired by deep-sea creatures, with artificial muscle, power and control electronics spread across a polymer matrix, successfully adapts to high pressure and operates in the deep ocean.