The inherent economic and social challenges in major cities have been known to foster stress among the urban population. Frequent stress over long periods may well have serious damaging outcomes, resulting in ailments such as burnout syndrome, sleeplessness and exhaustion, depression, feelings of panic, among others. Therefore, providing access to resources that may enable people to cope with the stress of urban life has become a crucial phenomenon in the twentieth century. Increasing empirical evidence indicates that the presence of natural areas can contribute to enhancing the quality of life in many ways. This study examines two historical Persian gardens from the residents' perspective in well-known, historic cities of Iran: Isfahan and Kerman. The data were collected through questionnaires (n = 252), semi-structured interviews (n = 20), and visual observation techniques. The findings demonstrate that nature, diversity and the gardens' historical background, and coherence motivate the residents' frequent visits to the gardens, which help to address their social, psychological, and physical needs. In addition, the residents' involvements and the variety of experiences that occur in the gardens lead to the creation of deeper meanings and values associated with the gardens. Subsequently, these construct functional and emotional attachment that evokes a sense of place and identity and may contribute to society's health and well-being.
Conventional building materials (CBMs) made from non-renewable resources are the main source of indoor air contaminants, whose impact can extend from indoors to outdoors. Given their sustainable development (SD) prospect, green building materials (GBMs) with non-toxic, natural, and organic compounds have the potential to reduce their overall impacts on environmental and human health. In this regard, biocomposites as GBMs are environmentally friendly, safe, and recyclable materials and their replacement of CBMs reduces environmental impacts and human health concerns. This study aims to develop a model of fully hybrid bio-based biocomposite as non-structural GBMs and compare it with fully petroleum-based composite in terms of volatile organic compound (VOC) emissions and human health impacts. Using a small chamber test (American Society for Testing and Materials (ASTM)-D5116) for VOC investigation and SimaPro software modeling with the ReCiPe method for evaluating human health impacts. Life cycle assessment (LCA) methodology is used, and the results indicate that switching the fully hybrid bio-based biocomposite with the fully petroleum-based composite could reduce more than 50% impacts on human health in terms of indoor and outdoor. Our results indicate that the usage of biocomposite as GBMs can be an environmentally friendly solution for reducing the total indoor and outdoor impacts on human health.
Cholesterol plays critical functions in arranging the biophysical attributes of proteins and lipids in the plasma membrane. For various viruses, an association with cholesterol for virus entrance and/or morphogenesis has been demonstrated. Therefore, the lipid metabolic pathways and the combination of membranes could be targeted to selectively suppress the virus replication steps as a basis for antiviral treatment. U18666A is a cationic amphiphilic drug (CAD) that affects intracellular transport and cholesterol production. A robust tool for investigating lysosomal cholesterol transfer and Ebola virus infection is an androstenolone derived termed U18666A that suppresses three enzymes in the cholesterol biosynthesis mechanism. In addition, U18666A inhibited low-density lipoprotein (LDL)-induced downregulation of LDL receptor and triggered lysosomal aggregation of cholesterol. According to reports, U18666A inhibits the reproduction of baculoviruses, filoviruses, hepatitis, coronaviruses, pseudorabies, HIV, influenza, and flaviviruses, as well as chikungunya and flaviviruses. U18666A-treated viral infections may act as a novel in vitro model system to elucidate the cholesterol mechanism of several viral infections. In this article, we discuss the mechanism and function of U18666A as a potent tool for studying cholesterol mechanisms in various viral infections.