Processos naturais de biodegradação do petróleo em reservatórios

Cruz, Georgiana Feitosa da; Marsaioli, Anita Jocelyne

doi:10.1590/s0100-40422012000800024

Cited by 10 publications

(8 citation statements)

References 60 publications

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“…The HDM can use hydrocarbons as a source of energy and carbon [58,59], preferably alkanes, cyclic and aromatic, and they metabolize organic and carbon compounds, drastically reducing oil quality [45,60]. With increasing levels of biodegradation, the content of asphaltenes and resins, acidity, and oil viscosity increase, while the content of saturated and aromatic hydrocarbons decreases [60,61]. These alterations have a negative effect on oil production by reducing the flow rates from reservoirs, as well as refining operations, and increasing process costs [61,62].…”

Section: Rna Amplification and Sequencing Methodsmentioning

confidence: 99%

Metabolically Active Microbial Communities in Oilfields: A Systematic Review and Synthesis of RNA Preservation, Extraction, and Sequencing Methods

Gomes,

García,

Dutra

et al. 2023

Applied Microbiology

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Characterizing metabolically active microorganisms using RNA-based methods is a crucial tool for monitoring and mitigating operational issues, such as oil biodegradation and biocorrosion of pipelines in the oil and gas industry. Our review, a pioneering study, addresses the main methods used to preserve, isolate, and sequence RNA from oilfield samples and describes the most abundant metabolically active genera studied. Using the MEDLINE/PubMed, PubMed Central, Scopus, and Web of Science databases, 2.561 potentially eligible records were identified. After screening, 20 studies were included in our review, underscoring the scarcity of studies related to the subject. Data were extracted and reported according to the Preferred Reporting Items for Systematic Reviews and Meta-Analysis (PRISMA). These studies evaluated different samples, including produced water (PW), injection water (IW), solid deposits (SD), oil (OIL), and oily sludge (OS) collected from oilfields located in Australia, China, India, Mexico, and the United Arab Emirates. Environmental samples accounted for 55% of the studies, while enriched cultures and microbial consortia represented 35% and 15% of studies, respectively. PW was the most frequently studied sample, comprising 72% of all samples. Filtration and centrifugation were the only processes employed to concentrate the biomass present in samples. For RNA preservation, the most used method was a solution composed of 95:5 v/v ethanol/TRIzol, while for RNA isolation, the TRIzol reagent was the most cited. The Sanger sequencing method was used in all studies evaluating functional genes (alkB, dsrA, aprA, assA, and mcrA), and the Next-Generation Sequencing (NGS) method was employed in studies for sequencing transcripts of the 16S rRNA gene and metatranscriptomes. Pseudomonas (16S rRNA = PW: 2%; IW: 8%; metatranscriptome = PW: 20%) and Acinetobacter (16S rRNA = PW: 1%; IW: 4%; metatranscriptome = PW: 17%) were the most abundant genera. This study outlined the primary methods employed in researching metabolically active microorganisms. These data provide a foundation for future research. However, it is essential to note that we cannot yet determine the most effective method. We hope that this study will inspire further research related to the standardization of RNA preservation, extraction, and sequencing methods and significantly contribute to our understanding of active microbial communities in oilfields.

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Section: Rna Amplification and Sequencing Methodsmentioning

confidence: 99%

Metabolically Active Microbial Communities in Oilfields: A Systematic Review and Synthesis of RNA Preservation, Extraction, and Sequencing Methods

Gomes,

García,

Dutra

et al. 2023

Applied Microbiology

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“…Dentre esses processos de alteração secundária do petróleo, a biodegradação ganha destaque por ser o processo de alteração secundária mais importante e devido ao volume de óleo pesado que tem sido explorado ao redor do mundo. Esta alteração é atribuída à ação de micro-organismos distintos (Milner et al 1977, Connan 1984, Palmer 1983, Blanc & Connan 1994, Peters et al 2005, Da Cruz et al 2008, Da Cruz et al 2011) e está vinculada a determinadas condições geológicas e geoquímicas que permitem melhorar a vida microbiana, tais como as existentes na interface óleo-água em um reservatório de petróleo (Larter et al 2006, Da Cruz & Marsaioli 2012. Segundo Peters et al (2005), as condições ótimas estão diretamente relacionadas ao fácil acesso ao petróleo e nutrientes inorgânicos (como o fósforo e traços de metais) presentes em reservatórios com temperaturas inferiores a 80 ºC, que são condições essenciais para a sobrevivência dos micro-organismos.…”

Section: Introductionunclassified

“…Além disso, é necessário que a rocha tenha permeabilidade e porosidade suficientes para permitir a difusão dos nutrientes e que a salinidade da água da formação não ultrapasse o limite de 150 ppm. Associado a todas essas condições, é imprescindível a presença dos micro-organismos biodegradadores e a ausência dos não-biodegradadores de hidrocarbonetos, os quais são considerados como "venenos naturais", visto que são tolerantes às condições dos reservatórios e inibem e/ou limitam o crescimento e atividade enzimática dos micro-organismos degradadores (Da Cruz 2009, Da Cruz & Marsaioli 2012.…”

Section: Introductionunclassified

“…Os efeitos mais notáveis da biodegradação envolvem a perda dos compostos mais leves, com a remoção seletiva iniciando-se preferencialmente pelos n-alcanos, alquilcicloexanos, seguida da remoção dos isoprenoides acíclicos e dos biomarcadores terpanos bicíclicos, esteranos, hopanos, diasteranos e esteroides aromáticos, com produção de novos compostos como produtos da biodegradação, tais como 17a, 25-norhopanos e ácidos carboxílicos (Chosson et al 1992, Moldowan et al 1992, Peters & Moldowan 1993, Da Silva 2008, De Lima et al 2010, Da Cruz & Marsaioli 2012.…”

Section: Introductionunclassified

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Caracterização geoquímica molecular de arenitos asfálticos a partir da desagregação branda de asfaltenos

Costa¹,

Martins²,

Cruz³

et al. 2013

Geochim. Bras.

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“…These are primarily consumed and do not promote methanogenesis, thereby inhibiting CH4 production. In the absence of TEAs such as sulfate and nitrate, hydrocarbons are converted into their end products (CH4 and CO2) (Cruz;Marsaioli, 2012;Tangen;. In the second campaign, where nutrients were enriched, there was also a higher concentration of TEAs, resulting in decreased methane emissions.…”

Section: Discussionmentioning

confidence: 99%

Greenhouse gas emissions (CO2, CH4 and N2O) in saline-alkaline systems of the Pantanal of Nhecolândia/MS

Melo¹

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Processos naturais de biodegradação do petróleo em reservatórios

Cited by 10 publications

References 60 publications

Metabolically Active Microbial Communities in Oilfields: A Systematic Review and Synthesis of RNA Preservation, Extraction, and Sequencing Methods

Metabolically Active Microbial Communities in Oilfields: A Systematic Review and Synthesis of RNA Preservation, Extraction, and Sequencing Methods

Caracterização geoquímica molecular de arenitos asfálticos a partir da desagregação branda de asfaltenos

Greenhouse gas emissions (CO2, CH4 and N2O) in saline-alkaline systems of the Pantanal of Nhecolândia/MS

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