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Article

03 July 2026

Strain Analysis for Grain Refinement and Mechanical Behaviour of AA5083 Processed Through Equal Channel Angular Pressing Technique

A metal forming technique called equal channel angular pressing is used to produce alloys and metals with ultrafine grain and nanocrystalline structure. Using this method, grain refining to the nano or submicron-scale is possible in materials with high strain super plasticity without affecting the size of the workpiece. One of the greatest techniques for creating bulk materials with ultra-fine grains is equal channel angular pressing. During this procedure, metal is continuously pushed through a channel die that has been particularly made with intersecting channels at different angles. The material is pass through a die in this procedure that has two channels that meet at a particular angle. Finer grains are formed as a result of the material’s deformation when it passes through the die. The creation of ultra-fine grains is influenced by a number of die design characteristics. The effects of processing route, corner angle, channel angle, and number of passes in die design on grain refinement. After comparing the results of several parameters, it was found that (90°) is the ideal channel angle for producing the maximum shear strain, and this strain reduces as the channel angle increases. The die was designed and produced in the lab with ideal design specifications, including a corner angle of (20°) and a channel angle of (90°). The mechanical characteristics of AA5083 were examined both before and after the Equal Channel Angular Pressing method. This study examines and analyses the mechanical behaviour of AA5083 that is treated through the use of an ECAP die that has ideal design specifications. Pressing was done between 0 and 2 times when using the (BC) path. According to the results, the grain size decreased from 480 nm to 170 nm, and the tensile strength increased from 225.8 MPa to 358.4 MPa after two ECAP runs.

Intell. Sustain. Manuf.
2026,
3
(2), 10017; 
Open Access

Article

02 July 2026

A Multi-Scale Assessment of Estuarine Fish Communities in Irrawaddy Delta

This study quantitatively analyzes fish community responses to environmental gradients in Myanmar’s Irrawaddy Delta. Integrating beta-diversity partitioning, Threshold Indicator Taxa Analysis (TITAN), single-season occupancy modeling, and Structural Equation Modeling (SEM), and species co-occurrence network analysis, we identified primary environmental filters shaping ichthyofaunal structure. Spatial comparison between Bogale and Pyapon ecosystems revealed fundamentally distinct communities driven predominantly by species turnover (87.1%). Network topologies further demonstrated a significant spatial restructuring of biological interactions, with the primary network hub role shifting from the highly sensitive Tenualosa ilisha in the upper estuary to the highly adaptable Macrognathus zebrinus in the lower delta. Furthermore, SEM established a substantial structural connection between environmental stress and biological assemblage response (β = 0.99), suggesting water quality as the ecosystem’s master driver. TITAN and occupancy models demonstrated an “estuarine enrichment” effect, where primary network hubs (Tenualosa ilisha, Coilia neglecta) reached peak occupancies only beyond high salinity thresholds (>18.16 ppt). However, escalating water temperatures act as a critical limiting factor, with a strict thermal boundary identified at 27.6 °C, beyond which sensitive taxa populations rapidly decline. These findings provide direct implications for adaptive fisheries management, underscoring the necessity of monitoring osmotic and thermal change-points to protect vital fisheries from compounded climate change impacts.

Open Access

Review

01 July 2026

Organoid Models of Liver Fibrosis: Bridging Genetic and Epigenetic Mechanisms with Biomarker Discovery

Fibrosis is a pathological process characterized by excessive deposition of extracellular matrix, progressive tissue stiffening, and ultimately organ dysfunction. It represents a common endpoint of chronic injury in multiple organs, including the liver, lung, kidney, and heart, and contributes substantially to global morbidity and mortality. Increasing evidence indicates that genetic susceptibility and dynamic epigenetic regulation play important roles in determining individual responses to chronic injury and in shaping fibrogenic signaling pathways. Despite its clinical significance, effective therapies remain limited, partly due to an incomplete understanding of the complex cellular interactions and molecular mechanisms that drive fibrotic disease. Traditional experimental models, including two-dimensional cell cultures and animal systems, often fail to fully recapitulate human tissue architecture and disease complexity. Organoid technology has emerged as a promising platform for modeling human diseases in vitro. Organoids are three-dimensional multicellular structures derived from stem cells or primary tissues that self-organize to mimic key structural and functional aspects of native organs while preserving important genetic and epigenetic characteristics of the originating tissue. Recent advances have enabled the development of organoid-based models that capture critical features of fibrosis, including epithelial injury, fibroblast activation, and extracellular matrix remodeling. These systems provide powerful experimental platforms for investigating molecular mechanisms of fibrosis, studying the influence of genetic and epigenetic regulatory networks, and identifying candidate biomarkers associated with disease progression. This review summarizes current progress in the use of organoid systems to study fibrosis across different organs. The advantages and limitations of these models are discussed, and emerging technologies that may enhance their physiological relevance and utility for biomarker discovery and anti-fibrotic drug development are highlighted.

Fibrosis
2026,
4
(3), 10011; 
Open Access

Article

01 July 2026

From Autonomy to Self-Determination: Intra-Familial Forms of Communication and Identity Perspectives in Situations of Rare Disability

This study explores communication, autonomy, and self-determination in individuals with Angelman syndrome (AS), a rare genetic condition characterised by severe intellectual disability and the absence of speech. AS is associated with severe developmental delay, motor disorders, epilepsy, hyperactivity, and a characteristically cheerful disposition. Communication is significantly impaired: expressive language is virtually absent, while receptive language is retained, giving rise to the use of Augmentative and Alternative Communication (AAC). The qualitative methodology draws on ethnographic fieldwork conducted with families, comprising six home observation sessions and sixteen semi-structured interviews with parents, childminders, or educators. The analysis examines the role of AAC and a form of ‘everyday communication’ through the lens of autonomy and self-determination. Although AAC has been recognised by the United Nations since 2006, it remains underused in everyday contexts owing to constraints of time and complexity. Multimodal communication relies on interpersonal interaction (gestures, eye contact, routines), thereby promoting functional autonomy (mobility, eating) and identity formation. Autonomy begins with survival (basic needs), under constant supervision necessitated by associated risks, and gradually evolves towards the expression of preferences (leisure activities, choices) through a co-constructed relationship. Self-determination incorporates relational and social dimensions through the progressive development of a positive identity despite dependence. In conclusion, AAC complements ‘everyday communication’ in supporting self-expression beyond the family sphere. Self-determination is grounded in meaningful exchanges that sustain identity notwithstanding intellectual disability. The recommendations aim to extend AAC to social contexts and to contextualise autonomy within an inclusive support framework.

Nat. Anthropol.
2026,
4
(3), 10012; 
Open Access

Review

01 July 2026

Residual Stress Characteristics in Additive/Subtractive Hybrid Manufacturing: A Review

This review methodically expounds on the genesis, distribution characteristics, and control methodologies of residual stress (RS) in additive/subtractive hybrid manufacturing (A/SHM). RS, originating from non-uniform temperature fields during manufacturing, rapid solidification of the molten pool, and complex thermal cycling, are key factors causing component deformation, performance degradation, and even cracking. It is evident that significant limitations are imposed on the industrial implementation of A/SHM technology in the domain of high-end equipment manufacturing. This review methodically unveils the influence patterns of process conditions, such as scanning strategies and laser parameters, on RS distribution. It elucidates the intrinsic relationship between microstructural evolution and RS and summarizes effective approaches to regulating RS through process optimization, post-heat treatment, and material modification. This paper proactively proposes a development direction for precise RS regulation through intelligent monitoring and control. This approach provides a theoretical foundation and technical support to enhance the reliability of A/SHM components and advance their industrial applications.

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