Your search keyword '"Delatolla, Robert"' showing total 7 results

1. Protocol for Evaluations of RT-qPCR Performance Characteristics: Technical Guidance

Author

Chik, Alex Ho Shing, Ann-Marie Abbey, Flemming, Cecily, Fletcher, Tim, Ho, Jane J.Y., Moustapha Oke, Pileggi, Vince, Raby, Melanie, Simhon, Albert, Thomas, Janis, Weir, Susan, D'Aoust, Patrick Marcel, Brown, Stephen, Tzu-Chiao Chao, Daigle, Jade, Delatolla, Robert, Dhiyebi, Hadi, Donaldson, Michael, Edwards, Elizabeth, Emelko, Monica, Qiudi Geng, Gilbride, Kimberley, Graber, Tyson, Kyle, Christopher, Mangat, Chand S., McDermott, Kevin, McKay, Mike, Oswald, Claire, Pang, Xiao-Li, Peng, Hui, Prostran, Natacha, Schmidt, Philip, Servos, Mark, Nivetha Srikanthan, Tehrani, Amir, Yang, Ivy, and Yuwei Xie

Published

2022

2. Plant-wide systems microbiology for the wastewater industry

Author

Cerruti, M., Guo, Bing, Delatolla, Robert, De Jonge, Nadieh, Hommes-De Vos Van Steenwijk, Aleida, Kadota, Paul, Mao, Ted, Oosterkamp, Margreet J., and Weissbrodt, D.G.

Abstract

The wastewater treatment sector embraces mixed-culture biotechnologies for sanitation, environmental protection, and resource recovery. Bioprocess design, monitoring and control thrive on microbial processes selected in complex microbial communities. Microbial ecology and systems microbiology help access microbiomes and characterize microorganisms, metabolisms and interactions at increased resolution and throughput. Big datasets are generated from the sequencing of informational molecules extracted from biomasses sampled across process schemes. However, they mostly remain on science benches and computing clusters, without reaching the industry in a clear engineering objective function. A bilateral bridge should actionize this information. As systems microbiologists, we miss that engineering designs and operations rely on stoichiometry and kinetics. The added-value provided by microbial ecology and systems microbiology to improve capital (CAPEX) and operating expenditures (OPEX) needs to be addressed. As engineers, we miss that microbiology can be provide powerful microbial information on top of physical-chemical measurements for quantitative process design (e.g., nutrient removal systems) with detailed scientific description of phenomena inside microbiomes. In this perspective article, we allied academia and industry to address the state of shared knowledge, successes and failures, and to establish joint investigation platforms. Our roadmap involves three milestones to (i) elaborate an essential list of microbiological information needed to implement methods at the process line; (ii) characterize microbiomes from microorganisms to metabolisms, and shape conceptual ecosystem models as primer for process ecology understanding; (iii) bridge engineering and mathematical models with an analytical toolbox for fast- vs. high-throughput analyses to discover new microbial processes and engineer assemblies. We praise for a harmonized "language of love"(incorporating common vocabulary, units, protocols) across the water and environmental biotechnology sector to team up mindsets for a sewer- and plant-wide integration of systems microbiology and engineering.

Published

2021

3. Nitrifying bio-cord reactor: performance optimization and effects of substratum and air scouring

Author

Tian, Xin, Ahmed, Warsama, and Delatolla, Robert

Subjects

6. Clean water

Abstract

Ammonia removal kinetics and solids’ production performance of the bio-cord technology are studied in this research. Three nitrifying reactors housing different bio-cord substratum were operated at five different ammonia loading rates. All of the bio-cord substrata demonstrated stable and high ammonia-nitrogen removal efficiencies of 96.8 ± 0.9%, 97.0 ± 0.6% and 92.0 ± 0.4% at loading rates of 0.8, 1.6 and 1.8 g NH4+-N/m2 d, respectively. At these same loading rates, the bio-cord reactors housing the three substrata also showed low solids’ production rates of 0.19 ± 0.03, 0.23 ± 0.02, 0.25 ± 0.03 g total suspended solids/d. A reduction of system stability, identified via fluctuating ammonia removal rates, was however observed for all substrata at loading rates of 2.1 and 2.4 g NH4+-N/m2 d. Further, the solids’ production rates at these higher loading conditions were also observed to fluctuate for all substrata, likely indicating intermediate sloughing events. The effects of enhancing the air scouring of the bio-cord on the ammonia removal rate was shown to be dependent upon the substratum, while enhanced air scouring of the bio-cord was shown to stabilize the production of solids for all substrata. This study represents the first performance and optimization study of the bio-cord technology for low-carbon nitrification and shows that air scouring of the substratum reduces sloughing events at elevated loading and that the bio-cord technology achieves stable kinetics above conventional rates of 1 g NH4+-N/m2 d to values of 1.8 g NH4+-N/m2 d.

4. Wastewater monitoring can anchor global disease surveillance systems

Author

Keshaviah, Aparna, Diamond, Megan B, Wade, Matthew J, Scarpino, Samuel V, Ahmed, Warish, Amman, Fabian, Aruna, Olusola, Badilla-Aguilar, Andrei, Bar-Or, Itay, Bergthaler, Andreas, Bines, Julie E, Bivins, Aaron W, Boehm, Alexandria B, Brault, Jean-Martin, Burnet, Jean-Baptiste, Chapman, Joanne R, Chaudhuri, Angela, de Roda Husman, Ana Maria, Delatolla, Robert, Dennehy, John J, Diamond, Megan Beth, Donato, Celeste, Duizer, Erwin, Egwuenu, Abiodun, Erster, Oran, Fatta-Kassinos, Despo, Gaggero, Aldo, Gilpin, Deirdre F, Gilpin, Brent J, Graber, Tyson E, Green, Christopher A, Handley, Amanda, Hewitt, Joanne, Holm, Rochelle H, Insam, Heribert, Johnson, Marc C, Johnson, Rabia, Jones, Davey L, Julian, Timothy R, Jyothi, Asha, Kohn, Tamar, Kuhn, Katrin G, La Rosa, Giuseppina, Lesenfants, Marie, Manuel, Douglas G, D'Aoust, Patrick M, Markt, Rudolf, McGrath, John W, Medema, Gertjan, Moe, Christine L, Murni, Indah Kartika, Naser, Humood, Naughton, Colleen C, Ogorzaly, Leslie, Oktaria, Vicka, Ort, Christoph, Karaolia, Popi, Patel, Ekta H, Paterson, Steve, Rahman, Mahbubur, Rivera-Navarro, Pablo, Robinson, Alex, Santa-Maria, Monica C, Schmitt, Heike, Smith, Theodore, Stadler, Lauren B, Stassijns, Jorgen, Stenico, Alberta, Street, Renee A, Suffredini, Elisabetta, Susswein, Zachary, Trujillo, Monica, Wolfe, Marlene K, Yakubu, Habib, and Zanoli Sato, Maria Ines

Abstract

To inform the development of global wastewater monitoring systems, we surveyed programmes in 43 countries. Most programmes monitored predominantly urban populations. In high-income countries (HICs), composite sampling at centralised treatment plants was most common, whereas grab sampling from surface waters, open drains, and pit latrines was more typical in low-income and middle-income countries (LMICs). Almost all programmes analysed samples in-country, with an average processing time of 2·3 days in HICs and 4·5 days in LMICs. Whereas 59% of HICs regularly monitored wastewater for SARS-CoV-2 variants, only 13% of LMICs did so. Most programmes share their wastewater data internally, with partnering organisations, but not publicly. Our findings show the richness of the existing wastewater monitoring ecosystem. With additional leadership, funding, and implementation frameworks, thousands of individual wastewater initiatives can coalesce into an integrated, sustainable network for disease surveillance—one that minimises the risk of overlooking future global health threats.

5. Hypoxic conditions in stormwater retention ponds: potential for hydrogen sulfide emission

Author

Liyu Chen, Delatolla, Robert, D’Aoust, Patrick M., Wang, Ru, Pick, Frances, Poulain, Alexandre, and Rennie, Colin D.

Subjects

6. Clean water

Abstract

Improper design and maintenance of stormwater ponds (SWPs) may lead to hypoxic conditions, poor water quality and the production of hydrogen sulfide (H2S). The objective of this study is to develop a comprehensive understanding of hypoxic conditions of SWPs, with a focus on the potential for H2S production and emission. This study was conducted at two retention SWPs in Ottawa, Canada; a problematic pond with the propensity for H2S emission and a reference pond that did not demonstrate H2S emission. The investigation illustrated a significant impact of low dissolved oxygen (DO) concentrations, hypoxic conditions, on the concentration of total sulfides in the water column. Both ponds were shown to periodically experience hypoxic conditions at depth, especially during summer periods with less precipitation and across longer periods of winter, ice-covered conditions. The problem pond, however, was shown to experience lower DO and longer hypoxic conditions than the reference pond in both non-ice-covered and ice-covered conditions due to greater depth and a longer hydraulic retention time. Hypoxic conditions were initiated at the deepest locations in the problem pond and subsequently were spread across the entirety of the pond under winter, ice-covered conditions. Algal biomass (Chlorophyll-a) and soluble biochemical oxygen demand concentrations were shown to not likely be significant factors in the development of hypoxia in the H2S-generating pond. Algal blooms of colonial Chrysophyceae, Synura, a known mixotroph, were observed during ice-covered conditions in the problem pond possibly due to stress-coping mechanisms of algae.

6. Hypoxic conditions in stormwater retention ponds: potential for hydrogen sulfide emission

Author

Liyu Chen, Delatolla, Robert, D’Aoust, Patrick M., Wang, Ru, Pick, Frances, Poulain, Alexandre, and Rennie, Colin D.

Subjects

6. Clean water

Abstract

Improper design and maintenance of stormwater ponds (SWPs) may lead to hypoxic conditions, poor water quality and the production of hydrogen sulfide (H2S). The objective of this study is to develop a comprehensive understanding of hypoxic conditions of SWPs, with a focus on the potential for H2S production and emission. This study was conducted at two retention SWPs in Ottawa, Canada; a problematic pond with the propensity for H2S emission and a reference pond that did not demonstrate H2S emission. The investigation illustrated a significant impact of low dissolved oxygen (DO) concentrations, hypoxic conditions, on the concentration of total sulfides in the water column. Both ponds were shown to periodically experience hypoxic conditions at depth, especially during summer periods with less precipitation and across longer periods of winter, ice-covered conditions. The problem pond, however, was shown to experience lower DO and longer hypoxic conditions than the reference pond in both non-ice-covered and ice-covered conditions due to greater depth and a longer hydraulic retention time. Hypoxic conditions were initiated at the deepest locations in the problem pond and subsequently were spread across the entirety of the pond under winter, ice-covered conditions. Algal biomass (Chlorophyll-a) and soluble biochemical oxygen demand concentrations were shown to not likely be significant factors in the development of hypoxia in the H2S-generating pond. Algal blooms of colonial Chrysophyceae, Synura, a known mixotroph, were observed during ice-covered conditions in the problem pond possibly due to stress-coping mechanisms of algae.

7. Nitrifying bio-cord reactor: performance optimization and effects of substratum and air scouring

Author

Tian, Xin, Ahmed, Warsama, and Delatolla, Robert

Subjects

6. Clean water

Abstract

Ammonia removal kinetics and solids’ production performance of the bio-cord technology are studied in this research. Three nitrifying reactors housing different bio-cord substratum were operated at five different ammonia loading rates. All of the bio-cord substrata demonstrated stable and high ammonia-nitrogen removal efficiencies of 96.8 ± 0.9%, 97.0 ± 0.6% and 92.0 ± 0.4% at loading rates of 0.8, 1.6 and 1.8 g NH4+-N/m2 d, respectively. At these same loading rates, the bio-cord reactors housing the three substrata also showed low solids’ production rates of 0.19 ± 0.03, 0.23 ± 0.02, 0.25 ± 0.03 g total suspended solids/d. A reduction of system stability, identified via fluctuating ammonia removal rates, was however observed for all substrata at loading rates of 2.1 and 2.4 g NH4+-N/m2 d. Further, the solids’ production rates at these higher loading conditions were also observed to fluctuate for all substrata, likely indicating intermediate sloughing events. The effects of enhancing the air scouring of the bio-cord on the ammonia removal rate was shown to be dependent upon the substratum, while enhanced air scouring of the bio-cord was shown to stabilize the production of solids for all substrata. This study represents the first performance and optimization study of the bio-cord technology for low-carbon nitrification and shows that air scouring of the substratum reduces sloughing events at elevated loading and that the bio-cord technology achieves stable kinetics above conventional rates of 1 g NH4+-N/m2 d to values of 1.8 g NH4+-N/m2 d.