Advancing Open Science

The role of poverty, specifically the urban poor, in shaping the urban landscape is often solely linked to slums and informal settlements in urban centers. However, contrary to this common perception, this study aims to elucidate how urban poor residents contribute to shaping urban sprawl in developing countries. After identifying patterns of urban sprawl and poverty in the Jakarta Metropolitan Area (JMA) in Indonesia, the study used the Structural Equation Model (SEM) method to analyze survey data from 195 respondents with a per capita income of less than USD 2.15 (IDR 34,000) daily in Tangerang Regency, a western suburb of the JMA. This study shows that urban sprawl and poverty concentration overlap. The urban poor contribute to urban sprawl by purchasing affordable land on the urban periphery, traveling there with their motorized vehicles, and taking advantage of government subsidies. However, rather than gaining more land, they face increased public service costs, a lack of basic facilities, and habitat destruction. Most respondents own their own homes, but almost half of the respondents (41.54%) state that these homes are less than 48 m² in size. It can be concluded that economically vulnerable populations can contribute to urban sprawl when confronted with ineffective planning institutions.

During the Joseon Dynasty, Korean Buddhism intentionally negotiated its survival and ongoing relevance in response to the predominance of Neo-Confucian state ideology by aligning Buddhist teaching with Confucian ethical ideals, especially filial piety. This process can be clearly observed in two well-known apocryphal texts—the Bulseol daebo bumo eunjung gyeong (佛說大報父母恩重經, Eunjung gyeong) and the Bulseol jangsu myeoljoe hojedongja darani gyeong (佛說長壽滅罪護諸童子陀羅尼經, Jangsu gyeong)—whose acceptance in Joseon Korea was largely dependent on their Confucian-inspired ethical substance. This article explores how the material aspects of these texts—such as woodblock printing methods, visual programs, book formats, and meticulous colophons—operated as means for integrating Buddhist doctrinal themes with Confucian moral standards. By focusing on the 1452 woodblock editions produced at Wŏnamsa Temple, this research highlights materiality as an influential factor in enabling the visual and ritual spread of Buddhist filial ethics and thereby supporting Buddhism’s cultural legitimacy in a Confucian-dominated environment. Using a material culture lens, this study addresses a notable gap in the current research—which has typically emphasized textual interpretation at the expense of material dimensions—and offers insight into how religious groups strategically utilized materiality to adapt within changing socio-cultural contexts.

Severe fluid loss in fractured, depleted reservoirs usually defeat conventional water-based drilling fluids (WBDFs), and rigid lost-circulation materials (LCMs) struggle to form durable, conformal seals. We report an eco-oriented colloidal gas aphron (CGA) fluid built from a nanostructured corn biopolymer (NCBP) and a biodegradable peanut-oil-derived surfactant, benchmarked against a reference fluid (RF) and aphron-only baselines (aphron based fluid, ABF). NCBP, produced by ball milling, was confirmed nanostructured by x-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), electron and atomic microscopies. Performance was evaluated from 25 to 90 °C for rheology, aphron stability and filtration at low temperature and low pressure (LTLP) of 100 psi and 25 °C, with post-test mud cake imaging. The optimized formulation, NCBP-2, showed stronger shear-thinning and higher gel strengths with heat, sustained stable and uniform aphrons for at least 120 min with foam persistence beyond 24 h, and delivered 3.0 mL filtrate with a 0.8 mm mud cake. These outcomes correspond to 60% less filtrate and approximately 73% thinner mud cakes than RF (7.5 mL; 3.0 mm), and about 14% and 33% improvements over the best ABF (3.5 mL; 1.2 mm). Micrographs revealed denser, finer-pored mud cakes, consistent with a mechanism in which deformable aphrons bridge micro-fractures while nano-scale polymeric fillers tighten the mud cake network. The results demonstrate decisive loss-control gains with temperature-tolerant rheology, supporting bio-based CGA fluids for depleted and fractured formations.

The goal of this study was to determine if a robot-assisted exercise system could lead individuals with Parkinson’s disease (PD) through different joint ranges of motion in a fun and effective manner. Eleven individuals with PD participated. A novel robotic system placed a target at different places in space for participants to tap with their hand, foot or knee. The range of motion (ROM) was collected by inertial measurement units (APDM), and was extracted using a custom code (Matlab). ROM was dependent upon the exercise and joint of interest. Participants illustrated acceptable levels of fatigue during each session, based on an average ending heart rate of 107.0 ± 11.9 bpm (~70% of maxHR) and an ending RPE of 6.5 ± 1.8 on a 10-point scale, indicating that the sessions were appropriately challenging. Standing forward reach, used to assess static balance and flexibility, improved by an average of 1.7 inches (p < 0.01), demonstrating immediate improvements from exercising with the robot. The results demonstrate the potential benefits of exercising with a robotic exercise system. The number of sessions spent with a PT can be limited by availability, so this system could be a fun way to encourage individuals with PD to complete their PT exercises at home.

This experimental review discusses evolutionarily approved, naturally pre-designed skeletal architectures of marine keratosan sponges in the form of 3D scaffolds, which have garnered increasing interest in the fields of structural and functional biomimetics as well as in tissue engineering. It has been demonstrated that these renewable, ready-to-use natural scaffolds can undergo further modifications through specialized treatments such as metallization and carbonization, enabling the creation of functional biomaterials while maintaining the species-specific hierarchical 3D structure. The study presented remarkable findings, including the demonstration of the unique shape-memory behavior of these scaffolds even after two months of exposure to high mechanical pressure at temperatures exceeding 100 °C. Additionally, the cytocompatibility and biological performance of natural and carbonized (1200 °C) spongin scaffolds, derived from selected bath sponges, were comparatively investigated with respect to growth and proliferation of human MG-63 osteoblastic cells. Understanding whether carbonization universally enhances osteogenic capabilities or selectively amplifies the inherent architectural advantages remains to be critical for the rational design of sponge-derived scaffolds in bone and structural tissue engineering applications.

Cordycepin is a key active component of Cordyceps militaris, but the molecular mechanism underlying temperature-regulated biosynthesis remains unclear. In this study, Cordyceps militaris strain KN-1 was used as experimental material, with low-temperature (15 °C), control (20 °C), and high-temperature (25 °C) treatments applied during the fruiting body stage. Transcriptomics, untargeted metabolomics, weighted gene co-expression network analysis (WGCNA), and Reverse Transcription quantitative PCR (RT-qPCR) validation were integrated to elucidate the molecular mechanism of temperature-mediated cordycepin biosynthesis. The results showed that 25 °C increased fruiting body cordycepin content by 84%, while 15 °C reduced it. Transcriptomic analysis identified differentially expressed genes (DEGs) enriched in transmembrane transport and fatty acid metabolism, and untargeted metabolomics revealed differential metabolites (DAMs) enriched in lipids and organic acids, indicating that temperature primarily affects Cordyceps militaris membrane function. WGCNA showed that the MEblue module was positively correlated with cordycepin (r = 0.93), with Major Facilitator Superfamily (MFS) members accounting for the highest proportion (47.1%) that may affect cordycepin transmembrane transport. Multi-omics analysis indicated that high temperature promotes cordycepin accumulation through the synergistic regulation of multiple pathways: upregulating genes in the pentose phosphate pathway, purine metabolism, and cordycepin biosynthetic gene cluster (Cns1–Cns3), increasing protective agent pentostatin content, downregulating cordycepin-degrading genes, and enhancing cordycepin transmembrane transport. This study clarifies the molecular mechanism of temperature-mediated cordycepin accumulation, providing a theoretical basis for improving cordycepin production via temperature regulation, optimizing Cordyceps militaris strain quality, and facilitating efficient industrial production.

This data descriptor presents a dataset comprising crop and soil parameters measured in winter wheat fields near the town of Knezha, Bulgaria. The data were collected as part of a project evaluating the potential of vegetation indices derived from Sentinel-2 satellite imagery to predict biophysical and biochemical crop parameters. The core dataset consists of measurements obtained from 20 m × 20 m field plots and includes a broad range of parameters: leaf area index, fraction of absorbed photosynthetically active radiation, vegetation cover fraction, chlorophyll content, above-ground biomass, plant nitrogen content, biological yield, surface soil moisture, spectral reflectance, plant density, crop height, visual assessments of disease or pest damage, and data on weed occurrence. The dataset is complemented by unmanned aerial vehicle imagery, crop calendars, and field management information. The main soil types in the study area were characterized through soil profiles, while meteorological data were obtained from an automated weather station. The data were collected during the 2016–2017 and 2017–2018 agricultural seasons. The dataset is freely available for download and serves as a valuable resource for researchers in remote sensing—particularly for validating satellite-derived products—as well as for specialists involved in winter wheat monitoring, modeling, and agronomic studies.

Toxoplasmosis is a globally prevalent protozoan parasitic disease of livestock, among others, with significant zoonotic potential. This study aimed to assess the seroprevalence of Toxoplasma gondii antibodies in serum samples from water buffaloes (Bubalus bubalis) in Sohag governorate, Upper Egypt. In addition, several factors related to animals, management, and environment were analyzed to identify the risk factors for T. gondii infection. A cross-sectional epidemiological approach was employed, with samples collected from various locations across the region and tested using a commercially available indirect enzyme-linked immunosorbent assay (iELISA). Animal and environmental factors were evaluated to identify potential risk factors for the disease. The overall seroprevalence of T. gondii among the tested buffaloes was 7% (24/342). Seasonal variations were observed, with the highest seropositivity recorded in spring (10.7%; 11/103), followed by autumn (8%; 2/25), summer (5.6%; 7/125), and winter (2.2%; 2/89). High seropositivity was detected in aborted females, at 19% (4/21), and in repeated breeders, at 10.5% (4/38), in relation to buffaloes showing anestrus (no positive cases), although the differences were not statistically significant. Our findings suggest that T. gondii is endemic in Sohag, with water buffaloes serving as sentinel animals for the disease. The spring season appears to be a risk factor for infection. Further studies are needed to assess the potential risk to humans, particularly regarding the consumption of raw or undercooked buffalo meat infected with T. gondii.