Development and testing of a 3D-printable polylactic acid device to optimize a water bioremediation process

Development and testing of a 3D-printable polylactic acid device to optimize a water bioremediation process

Abstract In the present work, a remediation bioprocess based on the use of a native isolate of Chlorella vulgaris immobilized in an alginate matrix inside a polylactic acid (PLA) device is proposed. This microalga immobilized in alginate beads was previously shown to be useful for the reduction of s...

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Main Authors: Patricia Laura Marconi, Andrea Trentini, Myriam Zawoznik, Carlos Nadra, Juan Manuel Mercadé, Juan Gabriel Sánchez Novoa, Daniel Orozco, María Daniela Groppa
Format: Article
Language:English
Published: SpringerOpen 2020-08-01
Series:AMB Express
Subjects:
Chlorella
PLA
3D-designed device
Matanza–Riachuelo watershed
Bioremediation
Bioprocess
Online Access:http://link.springer.com/article/10.1186/s13568-020-01081-9
id doaj-50dd2a185c0c471f911a0829a9aac38a
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spelling doaj-50dd2a185c0c471f911a0829a9aac38a2020-11-25T03:46:12ZengSpringerOpenAMB Express2191-08552020-08-011011910.1186/s13568-020-01081-9Development and testing of a 3D-printable polylactic acid device to optimize a water bioremediation processPatricia Laura Marconi0Andrea Trentini1Myriam Zawoznik2Carlos Nadra3Juan Manuel Mercadé4Juan Gabriel Sánchez Novoa5Daniel Orozco6María Daniela Groppa7CONICET, CEBBAD-Univ. MaimónidesCONICET, CEBBAD-Univ. MaimónidesIQUIFIB, FFyB, Universidad de Buenos AiresUniversidad Nacional de Tres de FebreroAPRA-CIFACEBBAD, Univ. MaimónidesCEBBAD, Univ. MaimónidesIQUIFIB-CONICET, FFyB, Universidad de Buenos AiresAbstract In the present work, a remediation bioprocess based on the use of a native isolate of Chlorella vulgaris immobilized in an alginate matrix inside a polylactic acid (PLA) device is proposed. This microalga immobilized in alginate beads was previously shown to be useful for the reduction of several chemical and microbial contaminants present in the highly polluted water from the Matanza–Riachuelo watershed. However, these beads had a relatively short shelf life in the natural environment. To overcome this limitation, a 3D-printed PLA device was designed. PLA is a biocompatible and biodegradable material suitable for biotechnological applications. We used Erlenmeyers and stirred-tank bioreactors fed batch with Murashige Skoog (MS) culture medium or water from the Cildáñez stream (one of the water bodies of the aforementioned watershed) to estimate the growth kinetics parameters and the bioremediation capacity of immobilized-microalgal cells as an unconfined system (UcS) or a confined system (CfS) inside PLA devices on Cildáñez water. Although alga’s growth parameters were maximum in the UcS fed with MS medium as substrate, successful bioremediation of the target water was possible using the CfS: all inorganic nitrogen forms and total phosphorus were reduced at least by 90% after 5 days of bioprocess in an agitated bioreactor, whereas aerobic mesophilic bacteria decreased by about 85%. The number of coliforms also decreased. Standardized cytotoxicity tests using Allium cepa seeds carried out to prove the effectiveness of the bioremediation process, confirmed the high degree of decontamination achieved by the use of immobilized microalga confined in a 3D-printable PLA-device.http://link.springer.com/article/10.1186/s13568-020-01081-9ChlorellaPLA3D-designed deviceMatanza–Riachuelo watershedBioremediationBioprocess
collection DOAJ
language English
format Article
sources DOAJ
author Patricia Laura Marconi
Andrea Trentini
Myriam Zawoznik
Carlos Nadra
Juan Manuel Mercadé
Juan Gabriel Sánchez Novoa
Daniel Orozco
María Daniela Groppa
spellingShingle Patricia Laura Marconi
Andrea Trentini
Myriam Zawoznik
Carlos Nadra
Juan Manuel Mercadé
Juan Gabriel Sánchez Novoa
Daniel Orozco
María Daniela Groppa
Development and testing of a 3D-printable polylactic acid device to optimize a water bioremediation process
AMB Express
Chlorella
PLA
3D-designed device
Matanza–Riachuelo watershed
Bioremediation
Bioprocess
author_facet Patricia Laura Marconi
Andrea Trentini
Myriam Zawoznik
Carlos Nadra
Juan Manuel Mercadé
Juan Gabriel Sánchez Novoa
Daniel Orozco
María Daniela Groppa
author_sort Patricia Laura Marconi
title Development and testing of a 3D-printable polylactic acid device to optimize a water bioremediation process
title_short Development and testing of a 3D-printable polylactic acid device to optimize a water bioremediation process
title_full Development and testing of a 3D-printable polylactic acid device to optimize a water bioremediation process
title_fullStr Development and testing of a 3D-printable polylactic acid device to optimize a water bioremediation process
title_full_unstemmed Development and testing of a 3D-printable polylactic acid device to optimize a water bioremediation process
title_sort development and testing of a 3d-printable polylactic acid device to optimize a water bioremediation process
publisher SpringerOpen
series AMB Express
issn 2191-0855
publishDate 2020-08-01
description Abstract In the present work, a remediation bioprocess based on the use of a native isolate of Chlorella vulgaris immobilized in an alginate matrix inside a polylactic acid (PLA) device is proposed. This microalga immobilized in alginate beads was previously shown to be useful for the reduction of several chemical and microbial contaminants present in the highly polluted water from the Matanza–Riachuelo watershed. However, these beads had a relatively short shelf life in the natural environment. To overcome this limitation, a 3D-printed PLA device was designed. PLA is a biocompatible and biodegradable material suitable for biotechnological applications. We used Erlenmeyers and stirred-tank bioreactors fed batch with Murashige Skoog (MS) culture medium or water from the Cildáñez stream (one of the water bodies of the aforementioned watershed) to estimate the growth kinetics parameters and the bioremediation capacity of immobilized-microalgal cells as an unconfined system (UcS) or a confined system (CfS) inside PLA devices on Cildáñez water. Although alga’s growth parameters were maximum in the UcS fed with MS medium as substrate, successful bioremediation of the target water was possible using the CfS: all inorganic nitrogen forms and total phosphorus were reduced at least by 90% after 5 days of bioprocess in an agitated bioreactor, whereas aerobic mesophilic bacteria decreased by about 85%. The number of coliforms also decreased. Standardized cytotoxicity tests using Allium cepa seeds carried out to prove the effectiveness of the bioremediation process, confirmed the high degree of decontamination achieved by the use of immobilized microalga confined in a 3D-printable PLA-device.
topic Chlorella
PLA
3D-designed device
Matanza–Riachuelo watershed
Bioremediation
Bioprocess
url http://link.springer.com/article/10.1186/s13568-020-01081-9
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