Design of a bio-conditioner prototype for the treatment of degraded soils: biomass production and lignite formulation for Microbacterium sp. CSB3

Background A new prototype of bio-conditioner useful in rehabilitation of degraded soils was performed. In order to obtain this aim two stages were established: production of biomass of Microbacterium sp. CSB3 and formulation of this inoculum in a sediment supplemented with low-rank coal (LRC). Mate...

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Bibliographic Details
Published in:Chemical and biological technologies in agriculture 2020-02, Vol.7 (1), p.1-11, Article 3
Main Authors: Pantoja-Guerra, Manuel, Valero-Valero, Nelson
Format: Article
Language:English
Subjects:
Agitation
Agriculture
Biomass
Biomedical and Life Sciences
Bioproduct formulation
Environmental risk
Growth rate
Heavy metals
Humic amendment
Inoculum
Life Sciences
Lignite
Microbial growth
Microorganisms
Optimization
Organic Chemistry
pH effects
Plant Biochemistry
Plant Physiology
Prototypes
Reactors
Rehabilitation
Sediment pollution
Sediments
Soil conditions
Soil degradation
Soil pollution
Soil Science & Conservation
Soil treatment
Soils
Viability
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Summary:Background A new prototype of bio-conditioner useful in rehabilitation of degraded soils was performed. In order to obtain this aim two stages were established: production of biomass of Microbacterium sp. CSB3 and formulation of this inoculum in a sediment supplemented with low-rank coal (LRC). Materials and methods The effect of agitation and pH on microbial growth was determined. As response variables, the final production of biomass (Xf) and yield (Yx/s) were determined. Growth dynamics of CSB3 in a 2-L reactor was also evaluated through Xf, Yx/s and the determination of kinetic parameters (specific growth rate [μ] and duplication time [Dt]). The formulation of CSB3 was evaluated; mixtures of several LRC proportions with a sediment from a municipal aqueduct were made. During 90 days, the viability of CSB3 was monitored by counting CFU. Results The optimal pH and agitation for Xf and Yx/x were 7.5 and 232 rpm, respectively; the values of Xf, Yx/s, μ and Dt in 2-L reactor were: 1.5 gL −1 , 0.28 g/g, 0.0208 h −1 , 33.3 h, respectively. Regarding the formulation, the most suitable combination to conserve the viability of CSB3 was LRC 25%–sediment 75%; the heavy metals content of LRC allow to infer that the prototype of bio-conditioner does not represent a pollution risk for environment soil. Conclusions It was possible to optimize the growth of CSB3 under laboratory conditions. The viability of CSB3 could be maintained by a formulation in a sediment supplemented with lignite; this formulation constitutes a new prototype of soil bio-conditioner.
ISSN:2196-5641
2196-5641
DOI:10.1186/s40538-019-0167-y