Guidelines for Nutrient optimization strategies Nutrient Nutrieent Plant Dtrategies Web Tool. Optimize Nutrient Removal WRRF Operations Webcast. Nramp5 is a Nutrient optimization strategies transporter responsible for manganese and cadmium uptake in rice. Grants Awarded. Expression and functional analysis of the CorA—MRS2—ALR-type magnesium transporter family in rice. Hernández D, Riaño B, Coca M, García-González MC Saccharification of carbohydrates in microalgal biomass by physical, chemical and enzymatic pre-treatments as a previous step for bioethanol production.

Nutrient optimization strategies -

Dragone G, Fernandes BD, Abreu AP et al Nutrient limitation as a strategy for increasing starch accumulation in microalgae. Appl Energy — Chokshi K, Pancha I, Ghosh A, Mishra S Salinity induced oxidative stress alters the physiological responses and improves the biofuel potential of green microalgae Acutodesmus dimorphus.

Fernandes B, Dragone GM, Teixeira JA, Vicente AA Light regime characterization in an airlift photobioreactor for production of microalgae with high starch content. Appl Biochem Biotechnol — Choix FJ, de-Bashan LE, Bashan Y Enhanced accumulation of starch and total carbohydrates in alginate-immobilized Chlorella spp.

Heterotrophic conditions. Enzyme Microb Technol — Silva CEF, Sforza E, Bertucco A Effects of pH and carbon source on Synechococcus PCC cultivation: biomass and carbohydrate production with different strategies for pH control.

Brányiková I, Maršálková B, Doucha J et al Microalgae-novel highly efficient starch producers. Biotechnol Bioeng — Miranda JR, Passarinho PC, Gouveia L Pre-treatment optimization of Scenedesmus obliquus microalga for bioethanol production.

Hernández D, Riaño B, Coca M, García-González MC Saccharification of carbohydrates in microalgal biomass by physical, chemical and enzymatic pre-treatments as a previous step for bioethanol production. Chem Eng J — Yu KL, Chen WH, Sheen HK et al Bioethanol production from acid pretreated microalgal hydrolysate using microwave-assisted heating wet torrefaction.

Fuel Rippka R, Deruelles J, Waterbury JB et al Generic assignments, strain histories and properties of pure cultures of cyanobacteria. J Gen Microbiol — Dubois M, Gilles KA, Hamilton JK et al Colorimetric method for determination of sugars and related substances.

Anal Chem — Van Wychen S, Laurens LML Determination of total carbohydrates in algal biomass determination of total carbohydrates in algal biomass: Laboratory Analytical Procedure LAP.

Ho SH, Huang SW, Chen CY et al Characterization and optimization of carbohydrate production from an indigenous microalga Chlorella vulgaris FSP-E. Kim KH, Choi IS, Kim HM et al Bioethanol production from the nutrient stress-induced microalga Chlorella vulgaris by enzymatic hydrolysis and immobilized yeast fermentation.

Lv JM, Cheng LH, Xu XH et al Enhanced lipid production of Chlorella vulgaris by adjustment of cultivation conditions. Qu W, Loke Show P, Hasunuma T, Ho SH Optimizing real swine wastewater treatment efficiency and carbohydrate productivity of newly microalga Chlamydomonas sp QWY37 used for cell-displayed bioethanol production.

Fernandes B, Dragone G, Abreu AP et al Starch determination in Chlorella vulgaris -a comparison between acid and enzymatic methods. J Appl Phycol — Ortiz-Tena JG, Rühmann B, Schieder D, Sieber V Revealing the diversity of algal monosaccharides: fast carbohydrate fingerprinting of microalgae using crude biomass and showcasing sugar distribution in Chlorella vulgaris by biomass fractionation.

Algal Res — Download references. This study was supported by the São Paulo State Research Foundation FAPESP, grants nos. Bioprocess and Metabolic Engineering Laboratory, School of Food Engineering, University of Campinas — UNICAMP, Monteiro Lobato N. Process and Product Development Department, Chemical Engineering Faculty, University of Campinas — UNICAMP, Campinas, SP, Brazil.

Gabriela F. Laboratory of Biotechnology, School of Chemistry and Food, Federal University of Rio Grande, Rio Grande, RS, , Brazil. You can also search for this author in PubMed Google Scholar. Conceptualization: Maria Augusta de Carvalho Silvello, Rosana Goldbeck; methodology: Maria Augusta de Carvalho Silvello, Giovana Alves Gasparotto, Gabriela F.

Ferreira; formal analysis and investigation: Maria Augusta de Carvalho Silvello; writing—original draft preparation: Maria Augusta de Carvalho Silvello; writing—review and editing: Maria Augusta de Carvalho Silvello, Gabriela F.

Ferreira, Leonardo V. Fregolente, Lucielen Oliveira Santos, Rosana Goldbeck; funding acquisition: Leonardo V. Fregolente, Rosana Goldbeck; Supervision: Rosana Goldbeck. Correspondence to Rosana Goldbeck. This article does not contain any studies with human or animal subjects performed by any of the authors.

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations. Springer Nature or its licensor e. a society or other partner holds exclusive rights to this article under a publishing agreement with the author s or other rightsholder s ; author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.

Reprints and permissions. de Carvalho Silvello, M. et al. Nutrient Optimization Strategy to Increase the Carbohydrate Content of Chlorella vulgaris and Evaluation of Hydrolysis and Fermentation Performance.

Download citation. Received : 27 January Accepted : 18 August Published : 06 September Issue Date : December Anyone you share the following link with will be able to read this content:. Sorry, a shareable link is not currently available for this article. Provided by the Springer Nature SharedIt content-sharing initiative.

Abstract Carbohydrate content of microalgae biomass can be increased and modulated. Access this article Log in via an institution. Data Availability All data generated or analyzed during this study are included in this article [and its supplementary information files].

References Saïdane-Bchir F, El Falleh A, Ghabbarou E, Hamdi M 3rd generation bioethanol production from microalgae isolated from slaughterhouse wastewater. Process Biochem —14 Article CAS Google Scholar Lim HR, Khoo KS, Chew KW et al Perspective of Spirulina culture with wastewater into a sustainable circular bioeconomy.

In addition to these resources, the research team hosted a part webcast series covering all facets of nutrient management. Results from the audience polls are incorporated into the report and available as a project paper. Published in Internal recycles, such as reject water and sidestreams from solids processing WRRFs can impact nutrient removal efficiency as well as create nuisance conditions.

Managing these recycles can improve nutrient removal Many biological nutrient removal BNR facilities incur excessive energy and chemical costs to meet stringent nutrient limits. As a result, there is strong incentive to reduce the operating The Nutrient Removal Challenge Challenge started in Since that time, several research projects were initiated as part of the Challenge, such as technology assessment meetings, and collaborative This research investigated the impact of advanced oxidation processes AOPs on the composition, speciation, and biodegradability of soluble nutrients in wastewater effluents in order to provide preliminary evaluation Nutrient management at water resource recovery facilities WRRFs is crucial for addressing water quality issues, especially in watersheds facing rapid urbanization and population growth.

Conventional biological nutrient removal This project seeks to further the prevention and control of harmful algal blooms HABs by improving full-scale applications of shortcut nitrogen removal processes at water resource recovery facilities Conventional biological nutrient removal BNR processes are energy-intensive and require sufficient carbon to reliably meet regulatory requirements.

There has been an increasing demand for sustainable, low carbon footprint Skip to main content. Back to Project List. Login to follow this project. Project Completion Year In Progress. Date Started Jan 1, Principal Investigator.

Research Manager. Related Topics Nutrients. Final Report. Abstract Resources Related Projects. Abstract Water resource recovery facilities WRRFs across the United States are facing demands to remove nutrients. Project Resources: Report and Executive Summary Path to Nutrient Optimization Web Tool 13 Webcasts Project Paper — Appendix E: Webinar Series Reports.

Resources Public Plus. Guidelines for Optimizing Nutrient Removal Plant Performance Report. View Executive Summary. Public Plus. Guidelines for Optimizing Nutrient Removal Plant Performance Webcast.

Guidelines for Optimizing Nutrient Removal Plant Performance Web Tool. Guidelines for Optimizing Nutrient Removal Plant Performance Project Paper. Nutrient Discharge Permitting and WRRF Optimization Webcast.

Tools to Evaluate Nutrient Optimization in WRRFs Webcast. Optimize Nutrient Removal WRRF Operations Webcast. This webcast will cover optimization strategies for nitrogen and phosphorus removal in nitrifying, conventional nutrient removal, and tertiary nutrient removal processes. Presenters will discuss ammonia, nitrogen, chemical, and biological phosphorus Nutrient Reduction Approaches for Small Systems Webcast.

This webcast will explain the nutrient regulatory landscape for small systems less than 10, people or 1 mgd and will cover tertiary treatment, stand-alone, pre-engineered, and natural systems.

Optimizing Nutrient Removal WRRFs Webcast. This webcast covered optimization strategies for nitrogen and phosphorus removal in nitrifying, conventional nutrient removal, and tertiary nutrient removal processes.

Presenters discussed ammonia, nitrogen, chemical, and biological phosphorus removal to They also covered strategies to reduce energy and chemical usage, e.

Instrumentation and Control for Nutrient Optimization — Part 2: Controls Webcast. Instrumentation and Control for Nutrient Optimization — Part 1: Sensors Webcast. This session provided an introduction to control systems, instrumentation, and strategies, with a focus on sensors. Fundamentals of sensors, including application, selection, installation, calibration, and maintenance will be covered.

Sidestream Management to Optimize WRRF Nutrient Removal Webcast. Beyond Liquid Treatment: Reduce Nutrient Discharge Loads by Other Means Webcast.

Technologies like algal treatment and nature-based solutions e. Emerging Technologies for Nutrient Optimization Webcast.

This webcast discussed emerging technologies for nutrient optimization of existing facilities, including emerging process developments, equipment, treatment and regulatory strategies, and overall system nutrient control approaches.

The webcast will focus Applied Fundamentals for Nitrogen and Phosphorus Removal Optimization Webcast. This webcast covered process fundamentals, focusing on implications and opportunities for optimizing nutrient reduction at WRRFs. Presenters went over the chemistry, microbiology, and processes used for nitrogen and phosphorus removal Nutrient Reduction from Secondary BOD Removal WRRFs Webcast.

High-intensity functional workouts resource is only available to Public Plus or Subscriber High-intensity functional workouts. If strztegies are not a Nktrient, you can register for a Public Plus stratgies. Need to login as a Subscriber and unsure if you have login credentials? Try resetting your password. If we have that email on file, you will receive an automated email with a reset link. If, after resetting your password, you still don't have subscriber access, please Contact Us. Login Now. How do sessile plants cope with irregularities in soil nutrient availability? The uptake of essential minerals from the soil influences plant growth and development. However, most oltimization do not Nutrient optimization strategies sufficient nutrients; rather nutrient oprimization in the soil can opptimization Nutrient optimization strategies and change temporally Nutrient optimization strategies to Cognitive function optimization methods factors. Nufrient maintain mineral nutrient homeostasis in their tissues, plants have evolved sophisticated systems for coping with spatial and temporal variability in soil nutrient concentrations. Among these are mechanisms for modulating root system architecture in response to nutrient availability. This review discusses recent advances in knowledge of the two important strategies for optimizing nutrient uptake and translocation in plants: root architecture modification and transporter expression control in response to nutrient availability. Recent studies have determined i nutrient-specific root patterns; ii their physiological consequences; and iii the molecular mechanisms underlying these modulation systems that operate to facilitate efficient nutrient acquisition.