Wall Erosion Research Articles

Seasonal Pattern of Endo-β-Mannanase Activity During Germination of Jeffersonia dubia, Exhibiting Morphophysiological Dormancy

Morphophysiological dormancy (MPD) is considered one of the most primitive dormancy classes among seed plants. While extensive studies have examined the occurrence of endo-β-mannanase in seeds with physiological dormancy (PD) or non-dormancy, little is known about the activity of this enzyme in seeds with MPD. This study aimed to investigate the temporal and spatial patterns of endo-β-mannanase activity during dormancy break and germination. The research focused on Jeffersonia dubia, a species with deep simple MPD, by monitoring its morphological and biochemical characteristics under natural field conditions. Seeds were buried in the field and exhumed monthly over a year. Key parameters measured included germination, embryo elongation, endosperm weakening, and endo-β-mannanase activity in the exhumed seeds. Scanning electron microscopy was employed to observe structural changes in the endosperm. For the first three months after burial in May, endo-β-mannanase activity was undetectable, and the underdeveloped embryo exhibited minimal elongation. Starting in September, the embryo began to grow, accompanied by increased endo-β-mannanase activity in the micropylar endosperm. Erosion of the endosperm cell wall was observed in the lateral regions surrounding the embryo, whereas the micropylar endosperm showed no obvious signs of collapse or damage. The increase in enzyme activity coincided with moderate temperatures and a corresponding increase in embryo length. During the winter months, embryo elongation ceased for 2–3 months, and enzyme activity declined. However, as germination resumed in early March, enzyme activity increased again. This was followed by micropylar endosperm rupture and the completion of germination. The seasonal pattern of endo-β-mannanase activity observed in seeds with deep simple MPD was distinct from that of seeds with PD, MD, or non-deep MPD, highlighting the unique mechanisms underlying dormancy break and germination in J. dubia.

Paranasal sinus mucoceles and its distortion of craniofacial-orbital anatomy: a narrative synthesis.

To explore available literature on PNS mucoceles and its distortions of craniofacial-orbital anatomy with regard to orbital bony defects and ophthalmic manifestations, highlighting the PNS mucoceles that mostly result in these distortions. A comprehensive literature search was conducted in June 2024 for available literature on the subject matter viz.; Google Scholar, PubMed and Medline, and Cochrane Library. Eligible studies were subjected to bias assessment. Extracted data from eligible studies were synthesized using narrative synthesis. Eighteen studies met the inclusion criteria. The 18 studies correspond to a total of 638 patients diagnosed with different types of PNS mucoceles, with males being the highest incidence of patients. Frontal, ethmoid, and fronto-ethmoidal mucoceles had the highest incidences (26.36%, 24.03%, and 23.29%, respectively). Orbital-bony defects, such as disruption and breach of the lamina papyracea, orbital wall erosion, and skull base erosion, were reported as the damage mostly caused by frontal and ethmoidal mucoceles. Ophthalmic manifestations such as proptosis, diplopia, ptosis, preorbital swelling, epiphora, vision problems, and exophthalmos were reported to occur in any type of the PNS mucoceles but are more common in mucoceles in the anterior sinuses. The narrative review summarizes the distortion of PNS mucoceles to craniofacial-orbital anatomy. Findings from this review will help to create more awareness of the extent of possible distortion that PNS mucoceles could have on craniofacial-orbital anatomy.

Imaging diagnosis and clinical outcomes of eight horses with sinus gas expansion

SummaryBackgroundSinus gas expansion is a rare condition in equine patients, resulting in progressive deformity of the facial bones. The condition is sparsely documented in veterinary literature. Similar lesions are categorised as sinus pneumocele or pneumosinus dilatans in human patients, based on the presence or absence of sinus wall erosion.ObjectivesTo describe imaging findings in horses with gas expansion of the paranasal sinuses.Study designMulticentric retrospective descriptive case series.MethodsHorses with a computed tomographic (CT) description of sinus gas expansion were included. Computed tomography changes were described, and lesions were categorised as sinus pneumocele or pneumosinus dilatans. Signalment, history and clinical signs were recorded, as well as radiological signs, histology and follow‐up information, when available.ResultsEight horses met the inclusion criteria, including seven diagnosed with sinus pneumocele and one with pneumosinus dilatans. Clinical signs were variable, depending on the affected bones and sinuses. The conchofrontal sinus was the most frequently affected. Irregular sinus wall erosion, marginal separation of the bone diploe and abnormal septation were consistent imaging findings in horses with sinus pneumocele. Active bone remodelling was confirmed by histology in one patient. Based on CT, the sinus mucosa was thickened adjacent to the sinus wall erosion in 5/7 patients, with hazy dystrophic mineralisation in three horses. One horse had a follow‐up CT at 26 months, showing progression of the lesion. The horse with pneumosinus dilatans had minor facial bone deformity and severe gas expansion of all left‐sided paranasal sinuses, largely encroaching on the right paranasal sinuses, without bone erosion.ConclusionDiagnostic imaging and more particularly CT is valuable for identifying and characterising abnormal gas expansion of the paranasal sinuses in horses. Based on this small case series, the condition is slowly progressive and inconsistently associated with clinical signs. Its pathophysiology remains unclear, warranting further exploration.

Cross-code comparison of the edge codes SOLPS-ITER, SOLEDGE2D and UEDGE in modelling a high-power neon-seeded scenario in the DTT

Abstract In this work, we cross-compare the state-of-the-art edge plasma codes SOLPS-ITER, SOLEDGE2D, and UEDGE in a reactor-relevant neon-seeded Divertor Tokamak Test (DTT) scenario at nominal power, extending the simplified test-bed of Moscheni et al. (2022). Converged solutions targeting the same separatrix density and radiated power are obtained by adjusting the pumping albedo and the neon puffing rate. This higher-power scenario is generally characterised by substantial disagreement between the three codes, up to 78-178% in peak heat fluxes. Discrepancies found in Moscheni et al. (2022) are indeed exacerbated, and new ones arise. Underlying causes include the over-penetration of neutrals implied by the unified ion-neutral temperature of UEDGE (observed in Moscheni et al. (2022)), here resulting in a 38-114% over-estimation of core plasma densities. The particular set of EIRENE atomic-molecular reactions adopted is found to stiffly restrict the achievable code solutions, which results in the predicted effective charge Z eff changing from ∽5 to ∽8 at the outer mid-plane separatrix. The strong link between Z eff, main ion density and unified ion temperature emphasises the need of proper assessments of impurity cross-field transport, with its implications on core contamination and wall erosion. The advantages of extended plasma meshes are found to come with associated modelling intricacies, yet to be fully characterised but seemingly impacting on the activity around the secondary X-point of single-null magnetic topologies. An appreciable impurity particle imbalance, generated by the neon ion density floor, is noted—speculatively contributing to SOLEDGE2D's different radiation emission distribution, and expected to be even more deleterious for high-Z impurities in all the codes. Potential drivers of further discrepancies are the different Braginskii formulations of collision times and momentum sources in presence of impurities, and the SOLPS-ITER extra terms gaining importance around the detachment front. Outstanding questions unanswered in this work prompt further investigations.

Iatrogenic Erosion of Orbital Walls due to Expanding Hydrogel Explant.

Hydrogel scleral buckles are a hydrophilic explant that may lead to significant delayed complications. They can insidiously enlarge over decades and may mimic an orbital tumor or cyst. The authors report a case of an expansive hydrogel scleral explant in a previously eviscerated socket. A 58-year-old male presented with a 2-week history of severe pain in his left anophthalmic socket. And 31 years prior, he had sustained OS trauma and undergone a series of surgeries. Details of these procedures were unavailable; however, he had ultimately proceeded to globe evisceration. MRI revealed a large lobulated cyst-like orbital mass with internal calcification, which had expanded the left orbit with erosion of the medial wall, lateral wall, and roof. It extended to involve the ethmoid and frontal paranasal sinuses. He proceeded to a lateral orbitotomy, revealing the lesion to be an expanded hydrogel scleral buckle explant. Postoperatively, there was a significant improvement in his pain.

Numerical prediction of cavitation erosion with emphasis on investigating the influence of driving pressure definition

This work devoted to analyzing the influence of the definition of driving pressure on the erosion prediction. For that, the density-corrected shear stress transfer turbulence model and the Sauer cavitation model are used to simulate the unsteady cavitating flow around a twisted hydrofoil. The numerical results were verified by compared to the cavitation shedding rate and the transient cavity behaviors in the experiment. The erosion energy in the flow field was defined based on the transient pressure and time-averaged pressure field, respectively, and the wall erosion load was predicted by mapping the erosion energy to the hydrofoil surface. It is found that using the time-averaged pressure as the driving pressure can predict more reasonable and more agreeable erosion simulation results, the instantaneous wall erosion load is more consistent with the transient evolution of cavity structures, and the distribution of accumulated wall erosion load is comparable to the erosion region in the experiment. Meanwhile, it is found that the main eroded area on the middle of the hydrofoil is caused by the continuous collapse of the small vapor structures shedding from the sheet cavity closure region, and the scattered pitting area in the middle of the trailing edge is mainly related to the ultimate collapse of cloud cavity.

Spray characteristics of axially-vaned slinger atomizer in air crossflow

Slinger atomizers are frequently employed to facilitate fuel spray atomization in aeroengine combustors. Unlike traditional radial slinger atomizers that induce the limited interaction between the rotating fuel and the surrounding air, this study proposes an innovative approach by incorporating axial vanes into the slinger rotor to potentially enhance fuel atomization performance. A comprehensive analysis of the spray characteristics of an axially-vaned slinger atomizer in air crossflow is numerically conducted, focusing on the effects of axial vane, rotor–stator axial clearance, and fuel inlet conditions. Results demonstrate that axially-vaned slingers outperform radial slingers by enhancing air swirl strength to disrupt the fuel jet, reducing the average droplet size by 25 % at 30000 rpm. Furthermore, positioning fuel nozzles farther from the rotor wall can mitigate the potential risk of surface thermal erosion. Fuel leakage through the rotor–stator clearance decreases from around 80 % at 10000 rpm to below 5 % at 30000 rpm and becomes negligible at 40000 rpm, thereby enhancing fuel–air mixing efficiency. Introducing supercritical fuel at the inlet facilitates its transition into a gaseous state within the slinger inner chamber, thereby markedly amplifying mixing efficiency. Nonetheless, this improvement is accompanied by a reduction in fuel flow rates. A significant aspect to consider is the heightened risk of substantial wall erosion due to pronounced leakage through the rotor–stator axial clearance. This study presents novel perspectives on improving the efficiency and ensuring the operational safety of rotary atomizers, thereby offering valuable guidance for the design of power and propulsion systems.

Improved erosion estimates for the STEP divertor

Net tungsten erosion and deposition profiles are simulated for the outer and inner lower divertor of STEP, a spherical prototype fusion reactor targeting ∼ 2040. In this contribution, previous modelling work [1] has been extended by studying the influence of various input parameters. Main aim is to analyse the influence of several modelling improvements on the erosion/deposition characteristics at the divertor targets. This comprises the consideration of an electron density decay according to the Boltzmann relation within the sheath region as well as a certain tungsten influx to the divertor originating from main wall erosion. Also, for the inner divertor improved background plasma parameters are applied taking into account a gradient along the flux surfaces compared to formerly constant electron temperature and density and ion temperature along the flux surfaces. ERO simulations have been performed for one selected plasma case with Ar seeding, both for the outer (with peak target Te ∼ 25 eV) and inner lower divertor (with peak target Te ∼ 3 eV).The simulated tungsten erosion and redeposition profiles do not significantly change for the cases studied if the Boltzmann-related decay of electron density within the sheath is considered. The assumption of tungsten within the background plasma can notably alter the overall erosion/redeposition behaviour at a background tungsten concentration of 1/10 with respect to the Ar divertor concentration. The inner divertor target plate shows net deposition everywhere, while at the outer one the net erosion zone becomes smaller and the maximum net erosion peak reduces by a factor of two. Lastly, the improved background plasma for the inner divertor has moderate effects, for instance the overall tungsten redeposition at the target plate increases from 88.7% to 94.4%.

ECVT imaging and CFD simulation of particle flow in a 90° bend

Gas-solid two-phase flow characteristics in a 90° bend within a pneumatic conveying system are critical for design and performance optimization, impacting conveying efficiency and system safety. Electrical Capacitance Volumetric Tomography (ECVT) and Computational Fluid Dynamics (CFD) simulations were employed in this study to investigate the flow characteristics in the bend. The ECVT system for bends was validated through static tests. A setup with a 36 mm inner diameter was constructed for high-speed 3D imaging of 0.9 mm quartz particles. Flow patterns, solid-phase concentration, particle velocity spectra, and mass flow rate were analyzed under various gas velocities. The Euler-Lagrange method and SST K-ω model were used to simulate particle flow and pipe wall erosion numerically. Results indicate diverse flow patterns across different gas velocities, where moderate turbulence enhances efficiency and limits erosion. This study offers an experimental basis for predicting and controlling particle motion, providing scientific guidance for optimizing pneumatic systems.

Comparative analysis of primary versus secondary paranasal sinus mucoceles: a case control study

Abstract Background Paranasal sinus mucoceles are benign cystic lesions characterized by mucous accumulation that can lead to significant complications due to erosion of sinus walls and compression of adjacent structures. This retrospective study aims to compare the clinical characteristics and treatment outcomes of primary and secondary mucoceles. Methods We reviewed medical records of 68 patients treated for mucoceles at the Ear, Nose, and Throat Hospital in Ho Chi Minh City, Vietnam, from June 2022 to June 2024. Advanced diagnostic imaging techniques, such as computed tomography (CT) and magnetic resonance imaging (MRI), were utilized in the management of these lesions. Statistical analysis was conducted using chi-square and t-tests to compare the characteristics and outcomes between the two groups. Results The study found that primary mucoceles often presented with less severe symptoms compared to secondary mucoceles, which occur post-surgery or post-trauma and are associated with more severe symptoms and complications. Primary mucoceles were most frequently located in the frontal-ethmoid region (47.4%), while secondary mucoceles had a similar distribution but were more prevalent following previous surgical interventions. Endoscopic sinus surgery was the primary treatment for both groups, with secondary mucoceles frequently requiring more complex surgical interventions. Postoperative improvement was significant in both groups, though secondary mucoceles exhibited slower recovery and higher rates of residual minor visual impairments. Conclusion The comparison between primary and secondary paranasal sinus mucoceles reveals critical differences in clinical profiles and treatment outcomes. Understanding these differences is essential for optimizing management strategies and improving prognosis for patients with these challenging conditions. Further research is needed to explore long-term treatment effects and the efficacy of different surgical approaches.

Numerical Prediction of Solid Particle Erosion in Jet Pumps Based on a Calibrated Model

Jet pumps are widely used in petrochemical processes, nuclear cooling, and wastewater treatment due to their simple structure, high reliability, and stable performance under extreme conditions. However, when transporting solid-laden two-phase flows, they face severe erosion problems, leading to reduced efficiency, malfunctions, or even failure. Therefore, optimizing jet pump performance and extending its service life is crucial. In this study, an experimental platform was established to conduct experiments on wall erosion in jet pumps. The CFD-DEM method was used to simulate the solid–liquid two-phase flow in the jet pump, comparing six erosion models for predicting erosion rates. The Grey Wolf Optimization algorithm was applied to calibrate model coefficients. The results indicate that the Neilson erosion model shows the best consistency with the experimental results. The inlet flow rate significantly influenced the erosion rates, while the flow rate ratio had a smaller effect. The particle concentration exhibited a nonlinear relationship with erosion, with diminishing impact beyond a certain threshold. As the factors varied, the erosion distribution tended to be uniform, but high erosion areas remained locally concentrated, indicating intensified localized erosion.

Insights into local wall erosion characteristics and prevention measures for cyclone separators

Cyclone separators are separation devices that use the principle of inertia to remove particulate matter from flue gases. The present study mainly focuses on wall erosion in cyclone separators and associated research. The main locations of erosion in gas–solid cyclone separators, including the entrance impact section, cyclone roof corner, vortex finder outer surface, spiral-type erosion strip, and lower cone section, are examined in detail. The main factors influencing wall erosion are discussed, including inlet flow velocity, solid particle properties and loading, geometrical structure, and manufacturing quality. Finally, several practically preventive measures against wall erosion are presented, including adjustment of operating conditions, the use of erosion-resistant materials, optimization of geometrical structures, and the addition of auxiliary devices, all of which are essential for ensuring operational efficiency, equipment reliability, safety, and environmental protection in various industrial applications. This paper aims to provide a basis for further research into erosion in cyclone separators as well as guidance for engineers involved in their industrial applications.

Optimizing Fish Feed Pellets Handling Systems to Minimize Microplastics Emissions - A Pilot Test Based Approach

The fisheries and aquaculture industries are vital components of global food production, yet they also contribute to release of microplastics into marine environments, posing risks to ecosystem health and seafood safety. Among the contributing factors, the erosion of feeding pipes during the pneumatic conveyance of fish feed pellets stands out as a significant source of microplastic pollution. This study focuses on optimizing feed pellet conveying systems in fish farms to minimize microplastic emissions while maximizing pipeline lifespan and pellet integrity. Using high-density polyethylene (HDPE) pipes commonly found in aquaculture facilities, the impact of air velocity and pipeline configuration on pipe wall erosion and pellet breakage was investigated. Through pneumatic conveying tests, the effects of varying air flow rates and bend radii were assessed on pipeline wear and feed pellet integrity. The findings of the study underscored the importance of optimizing operating parameters to bring a balance between preventing pipe blockages and minimizing abrasive impacts on pellets and pipeline surfaces. Furthermore, a simulationbased approach to optimize feeding system performance is presented, integrating the experimental results into a computational model. This model allows for the evaluation of different operating conditions and pipeline configurations, offering insights into costeffective strategies for reducing microplastic emissions while maintaining efficient feed delivery to fish populations. Ultimately, this research provided practical recommendations and best practices for the aquaculture industry to mitigate microplastic pollution from feeding pipes. By optimizing feed pellet conveying systems, environmental sustainability can be enhanced, seafood quality be preserved, and bolster consumer confidence in aquaculture products.

Impact of the Draft Plate on the Wall Erosion and Flow Field Stability of a Cyclone Separator

Cyclone separators are commonly employed in the mining, metallurgy and chemical industries due to their simple structure, easy maintenance and high recovery efficiency. However, with the wide application of cyclone separators, many problems have become exposed in their practical operation, restricting their development. Among these, wall erosion is becoming a significant problem. In this study, to resolve the problem of severe erosion on the walls, the Eulerian–Lagrangian framework was employed to investigate a cyclone separator with a draft plate at the inlet and to evaluate the effect of a draft plate with angles of 0°, 45° and 90° on the degree of erosion and the stabilization of flow fields. Moreover, after verifying the reliability of the numerical model via data from experiments, the characteristics of gas–solid flow were analyzed and the effects of the new structure on the degree of wear were investigated. The results demonstrated that unfavorable phenomena such as secondary flow and wall erosion generated during the operation could be mitigated by the draft plate. When the plate angle was 90°, the wall erosion was the lightest and the range of influence of the secondary flow was the smallest. When the plate angle was 45°, the comprehensive performance was the best, and there was a better balance between the energy loss and the degree of wall erosion. Therefore, the presence of the draft plate has a significant impact on the interaction of gas–solid phases in a cyclone separator.

Management of a Rare Case of Superior Mesenteric Artery Aneurysm Associated with a Pancreatic Cyst Complicated by Acute Rupture: A Case Report and Review of Literature.

Superior mesenteric artery aneurysms are a rare pathology, and rupture due to a pancreatic cyst in the context of alcohol-induced pancreatitis is an even rarer condition. The first line of treatment is usually an endovascular approach. We present the case of a 51-year-old male with alcohol-induced pancreatitis, diagnosed with a superior mesenteric artery aneurysm with active bleeding in close contact with a large pancreatic cyst. A covered stent was used to treat this condition. The patient developed hemorrhagic shock 12 h after the procedure and an urgent laparotomy was performed. A second rupture of the arterial wall at the distal end of the stent was observed and in order to obtain distal perfusion, first, an infrarenal aorta to superior mesenteric artery bypass distal to the rupture was performed in order to exclude the aneurysm. Secondly, a bypass originating from the distal end of the first bypass to the distal end of the superior mesenteric artery was performed. The patient had an uneventful recovery and was discharged after 10 days. We reviewed the literature regarding the incidence and the therapeutic management of superior mesenteric artery aneurysm complicated by pancreatic cyst. An advanced search on PubMed from 2004 to 2024 returned 194 results and after applying the inclusion-exclusion criteria, 11 publications were selected. Although the endovascular approach is usually the first line of treatment with obvious advantages for the patient, a patient-tailored approach should be made in such cases and surgery could be the first option, when considering that the mechanism of aneurysm rupture is due to erosion of the arterial wall by the pancreatic enzymes. Surgery has the advantage of cyst drainage and aneurysm exclusion and in our case proved lifesaving.

DDPM investigation on centrifugal slurry pump with inlet and sideline configuration retrofit

The inlet and sideline configuration modifications are widely investigated to alter regional particle fluid flow conditions, considering pressure, turbulence and erosion, therefore to improve energy saving and compartment longevity of centrifugal slurry pump. This paper aims to analyse pump hydraulic and erosion characteristics with proposed pump sideline and inlet configuration retrofit by the DDPM method. Specifically, the inlet guide vane number () and angle (), and sidelining vane (SDV) curvature are investigated in quantitative manner. Accordingly, by adjusting inlet vane configuration and placement, a trade-off between wall erosion and hydraulic performance is observed. The sidelining vane (SDV) design is suggested to avoid resultant counter-current flow formulation, therefore, to mitigate turbulence induced erosion in impeller and volute. However, the SDV modification effect on pump hydraulic head and efficiency is found marginal. In general, this study offers realistic guideline for performance improvement and device upgrading of centrifugal slurry pumps.

Helium retention feature in the boron deposited layer on tungsten substrate by laser-induced breakdown spectroscopy and machine learning approach

ITER is designed for a burning plasma operation in which Tungsten (W) tiles are used as the first wall and diverter materials. Studying He dynamics in B-coated W wall is essential to understanding the effect of boronized plasma-facing components in fusion reactors, as these post-conditioning materials significantly influence helium retention and release. Plasma-wall interactions (PWI) are an important issue in ITER fusion reactors. PWI would lead to wall erosion and impurity redeposition. As a product of the D-T burning plasma, helium (He) ash would be retained or co-deposited on plasma-facing components (PFCs), affecting the stable operation of burning plasma. Laser-induced breakdown spectroscopy (LIBS) is proposed as a promising in-situ diagnostic approach for monitoring D/T and He retention and impurity deposition on PFCs of tokamak devices. In this study, the LIBS technique was used to investigate the helium retention feature in the boron (B) layer on tungsten substrate in 10−5 mbar. Five He-retention samples on the boron deposition layer on tungsten substrates were prepared by pulsed laser deposition (PLD) method at different ambient pressures in our lab. The investigations indicate that the atomic spectral line of helium (He-I 587.56 nm) was observed in the spectra of the first three laser shots. The depth profiles of He, B, and W in the boron-deposited layer on tungsten substrate were performed by LIBS to determine the co-deposition layer thickness. The concentration of He in the co-deposition layer samples measured by TDS is 7 × 1020 He/m2. The plasma parameters, such as plasma electron temperature and electron number density, were calculated to validate the local thermodynamic equilibrium. Machine learning (ML) algorithms are used to classify the co-deposits and substrates. The first three principal components (PC1, PC2 & PC3) of the unsupervised ML algorithm (PCA) give a classification accuracy of 91.7 %. The supervised ML algorithm neural network achieved training and testing accuracy of 100 % and 96.7 %, respectively.

Determination of Optimal Bottom Blowing Angle for Improving Mixing Efficiency and Wall Erosion in Steel-Making Converter: Numerical Modeling and Engineering Application

Determination of Optimal Bottom Blowing Angle for Improving Mixing Efficiency and Wall Erosion in Steel-Making Converter: Numerical Modeling and Engineering Application

Effect of Solid Particles in Polymer Waste Liquid on Grinding Tool Wall Erosion

Abstract With the continuous accumulation of polymer waste liquid in the third oil recovery process, the treatment of wellhead return waste liquid has become a key issue in oilfield exploitation and environmental protection. In this paper, the erosion failure of the cutter caused by sand-containing particles in the waste liquid during the shear grinding process is studied. The influence of the main structural parameters of the grinding tool and the erosion failure is studied by using the comprehensive numerical simulation method to reduce the erosion rate of the polymer flooding waste liquid on the cutter. Firstly, the flow field model of the solid-liquid fluid is established, and the erosion phenomenon on the tool wall is studied by combining the model with field experiments. In addition, the relationship between the different cutters structure and erosion rate of the grinding tool is studied, and the mathematical model is established. The optimized structural parameters are given to enhance the erosion resistance of the grinding tool in the process of polymer flooding wellhead waste liquid treatment and prolong its service life.

Cochlear implantation in otosclerosis: surgical and audiological outcomes between ossified and non-ossified cochlea.

To evaluate (1) Audiological and surgical outcomes in patients with otosclerosis following cochlear implantation. (2) surgical difficulties and outcomes between both groups. (3) Audiological outcomes between both groups. Retrospective study conducted at Otology and Skull Base Surgery Center. Data were analyzed from 111 patients with otosclerosis (114 ears) who underwent cochlear implant surgery using the cochlear implant database. Demographic characteristics (age, sex, and operated ear), auditory outcomes, and operative details (extent of cochlear ossification, surgical approach [posterior tympanotomy or subtotal petrosectomy], electrode insertion [partial/complete, scala tympani or vestibuli], and complications) were analyzed Auditory outcomes were assessed over at least one year follow-up period using pure tone audiometry and speech discrimination scores. Patients were divided into two groups (with and without cochlear ossification) to compare auditory outcomes and surgical outcomes. The mean age of patients with ossified and non-ossified cochlea was 60.04 and 62.22years respectively. Sixty-five of 114 ears had cochlear ossification, with complete round window involvement in 75.4% of these patients, while the rest had partial or complete basal turn ossification. Subtotal petrosectomy was performed in 63.1% and 28.6% of ossified and non-ossified cochlea respectively while the rest underwent cochlear implantation through posterior tympanotomy. Only one case had scala vestibuli insertion and four had incomplete electrode insertion. Six patients underwent re-implantation due to infection, device failure, and erosion of the posterior canal wall. Auditory outcomes among patients with ossified otosclerosis were slightly better than those without ossification but this difference was not statistically significant. Cochlear implantation for otosclerosis yields excellent auditory outcomes with a low rate of surgical complications, despite the high incidence of cochlear ossification.