Combined sewer overflow mitigation through SUDS - A review on modelling practices, scenario elaboration, and related performances.

Hydrologic-hydraulic modelling of urban catchment is an asset for land managers to simulate Sustainable Urban Drainage Systems (SUDS) implementation to fulfil combined sewer overflow (CSO) regulations. This review aims to assess the current practices in modelling SUDS scenarios at large scale for CSO mitigation encompassing every stage of the modelling process from the choice of the equation to the validation of the initial state of the urban system, right through to the elaboration, modelling, and selection of SUDS scenarios to evaluate their performance on CSO. Through a quantitative and qualitative analysis of 50 published studies, we found a diversity of choices when modelling the status quo of the urban system. Authors generally do not explain the modelling processes of slow components (deep infiltration, groundwater infiltration) and interconnexion between SUDS and the sewer system. In addition, only a few authors explain how CSO structures are modelled. Furthermore, the modelling of SUDS implementation at catchment scale is highlighted in the 50 studies retrieved with three different approaches going from simplified to detailed. SUDS modelling choices seem to be consistent with the objectives: studies focusing on dealing with several objectives at the time typically opt for a complex system configuration that includes the surface processes, network, CSO, SUDS, and often the soil and/or groundwater components. Conversely, authors who have selected a basic configuration generally aim to address a single, straightforward question (e.g., which type of SUDS). However, elaboration and selection of scenarios for CSO mitigation is mainly based on local constraints, which does not allow hydrological performance to be directly optimised. In conclusion, to improve current practices in modelling SUDS scenarios at large scale for CSO mitigation, authors suggest to: (i) improve clear practices of CSO modelling, calibration and validation at the urban catchment scale, (ii) develop methods to optimize the performance of scenarios for CSO mitigation using hydrological drivers, and (iii) improve parsimonious and user-friendly models to simulate SUDS scenarios in a context of data scarcity.

Micropollutants removal and storage efficiencies in urban stormwater constructed wetland.

Stormwaters is identified as a major source of pollution in waterbodies. Particularly, heavy metals (HMs) and Polycyclic Aromatic Hydrocarbons (PAHs) in stormwater are highly toxic compounds for living organisms. To limit the impact of these micropollutants on hydrosystems quality, stormwater constructed wetlands (SCWs) have been built worldwide. This study aims to i) assess the efficiency of a SCW that combines a sedimentation pond followed by a vertical flow sand filter in urban area (Strasbourg 67, France) and ii) determine micropollutants storage in water and soils during dry periods. Stormwater quality was analysed during 13 sampling sessions and the SCW storage ability during dry period was highlighted. The rainfall events sampled are characterized by very high variability: dry periods lasted from 5 h to 10 d, rain durations varied from 15 min to 22 h and the return periods were between 2 and 4 wk. and 3-6 mo. The inflow stormwater included a high amount of Zn and a variety of PAHs. Cu, Zn and some PAHs concentrations are impacted by hydrological characteristics. During a rain event, the filter catches the majority of both dissolved and particulate micropollutants and the mobilization of particulate micropollution by incoming flow decreases pond removal efficiency. The treatment removal efficiency varied from 50% (naphthalene) to 100% (particulate Zn). Four HMs (Co, Cu, Pb, Zn) were found in the pond and seven (Cd, Cr, Co, Cu, Ni, Pb, Zn) in the filter during a dry period at high concentrations compared to their occurrence in rainfall. A release of HMs from the filter sand to the interstitial water is highlighted. In water and the soil matrix, PAHs occurrence was consistent with their water solubility, logKow and logKoc.

Urban stormwater treatment by a constructed wetland: Seasonality impacts on hydraulic efficiency, physico-chemical behavior and heavy metal occurrence.

Urban stormwater affects the general quality of water bodies because of their hydraulic and pollution impacts. Stormwater discharges modify stream water flow and are reported as major source of heavy metals (HMs) in urban streams. Stormwater Constructed Wetlands (SCWs) have been built worldwide to manage stormwater before it is released into hydrosystems. In SCWs, stormwater is stored, evaporated and sometimes infiltrated. Subsequently, the HMs in stormwater can be settled, filtered and bioassimilated by microorganisms. Hence, the efficiency of SCWs in managing stormwater depends on climatic conditions, which change with season. The aim of this study was to investigate the impacts of seasonality on the performance of a 6-year-old constructed wetland made with a pond followed by a vertical flow filter. Hydraulic performance of, physico-chemical behaviour of, and HM mitigation via the SCW were evaluated using over 3 years of monitoring (2015-2017) data. Only 35% of the rain events that occurred in the studied catchment caused a discharge into the pond and 17% into the filter. The SCW was mostly supplied with stormwater in spring and summer and provided peak flow attenuation from 97 to 100% in all seasons. Variations in physico-chemical parameters (temperature, dissolved oxygen, pH, and redox potential) were caused by seasonal and dry/wet weather changes. They were greater in the pond than in the filter, which buffers these variations. The high physico-chemical variations in the pond probably had a deleterious effect on HM storage in the pond sediments. Finally, hydrologic and physico-chemical conditions (antecedent dry period length, pH, redox potential) affected the HM concentrations along the SCW. However, HM removal efficiencies were >97% in all seasons.

Intraepithelial T-lymphocyte subsets in the airways of normal subjects and of patients with chronic bronchitis.

Lymphocyte infiltration of central airway epithelium was evaluated in 13 normal nonsmoking subjects (Group 1), in 11 smokers without clinical signs of chronic bronchitis (Group 2), and in 34 patients who were smokers with chronic bronchitis and mild airflow limitation (Group 3). Bronchial samples were obtained through fiberoptic bronchoscopy. Murine monoclonal antibodies directed against cell-surface antigens and an immunoperoxidase technique were used on cryostat sections to label in situ the following lymphocyte populations: T-lymphocytes (CD3+), helper/inducer T-cells (CD4+), suppressor/cytotoxic T-cells (CD8+) and B-lymphocytes (leu 12+). Virtually no B-cells were found in central airway epithelium from subjects of any group. Conversely, consistent infiltration of epithelial layers with T-lymphocytes of both subsets was observed in all subjects, with a constant predominance of CD8+ over CD4+ cells. For any T-cell marker, differences between mean scores from Group 1 and Group 2 subjects were not statistically significant. On the other hand, mean lymphocyte numbers of both subsets were found increased in patients from Group 3 compared with subjects from the two other groups: statistically significant differences were observed for CD3+, CD4+, and CD8+ cells (p less than 0.001). Furthermore, lymphocyte scores at two different airway generation were compared in some patients from Groups 2 and 3, and a significant positive correlation was observed. These results suggest that T-lymphocyte infiltration of central airway epithelium (1) may be a naturally occurring phenomenon that is amplified in the airways of smokers with chronic bronchitis, and (2) may represent the counterpart to the intraepithelial population of the intestine.(ABSTRACT TRUNCATED AT 250 WORDS)

Morphological changes in rat tracheal mucosa immediately after antigen challenge.

We have investigated the morphological effects of an intratracheal challenge with 50 micrograms ovalbumin (OA) on sensitized rat tracheas, in vivo. Female Sprague-Dawley rats were primed ten days before challenge with a single i.t. injection of 100 micrograms OA plus Bordetella pertussis (OA-BP). Two additional groups of animals served as controls: primed animals challenged with saline only and non-primed but OA-challenged animals. Sacrifices--and subsequent morphological studies--were performed prior to and 5, 15 and 60 min after challenge. At each time, the total numbers of epithelial nuclei, subepithelial mast cells (SEMC) and intraepithelial mast cells (IEMC) were scored in six non-adjacent cross sections per trachea. We found that: 1) priming with OA-BP alone did not induce any change in the tracheal mucosa with respect to morphological structure and mast cell counts; 2) no morphological change nor significant modification of the cell counts occurred at any time in tracheas from either of the control groups; 3) in contrast, a luminal heterogeneous exudate and a subepithelial oedema developed in 9 of the 15 tracheas of primed animals within 60 min of OA challenge. In those nine tracheas, the scores of intraepithelial nuclei, of IEMC and of SEMC were found to decrease significantly 15 min after challenge as compared with starting values (p less than 0.05 for each score). The decrease in the number of mucosal mast cells is probably related to the damages of the epithelial cells and to the difficulty with which depleted mast cells can be seen by toluidine blue staining.