Estudos preliminares de Adsorventes Lenhocelulósicos para a Remoção de Cefalosporinas

Luísa Cruz Lopes; Rodrigo Araújo; Ana Lopes; Morgana Macena; Bruno Esteves

doi:10.29352/mill0216e.40973

Autores

Luísa Cruz-Lopes Instituto Politécnico de Viseu, Viseu, Portugal | CERNAS – Research Centre for Natural Resources, Environment and Society, Viseu, Portugal https://orcid.org/0000-0001-6502-7202
Rodrigo Araújo Instituto Politécnico de Viseu, Viseu, Portugal
Ana Lopes Universidade Católica Portuguesa, Viseu, Portugal https://orcid.org/0000-0002-4415-7558
Morgana Macena Instituto Politécnico de Viseu, Viseu, Portugal | CERNAS – Research Centre for Natural Resources, Environment and Society, Viseu, Portugal https://orcid.org/0000-0002-2833-5465
Bruno Esteves Instituto Politécnico de Viseu, Viseu, Portugal | CERNAS – Research Centre for Natural Resources, Environment and Society, Viseu, Portugal https://orcid.org/0000-0001-6660-3128

DOI:

https://doi.org/10.29352/mill0216e.40973

Palavras-chave:

adsorción; modelos cinéticos; materiales lignocelulósicos; cefalosporina; Acacia dealbata

Resumo

Introdução: A Acacia dealbata foi explorada como biosorvente para remover cefalosporina de soluções aquosas. Este estudo procura demonstrar a viabilidade de utilizar materiais lenhocelulósicos de baixo custona remoção de poluentes, valorizando resíduos de outras indústrias e reduzindo o impacto ambiental associado.

Objetivo: O objetivo pretendeu avaliar a capacidade dos resíduos de acácia em adsorver a cefalosporina, analisando o seu potencial de adsorção e os modelos cinéticos envolvidos, de forma a explorar o seu uso no tratamento de águas.

Métodos: Esta revisão foi conduzida utilizando uma abordagem sistemática para identificar, analisar e sintetizar a literatura relevante sobre a presença e o impacto dos antibióticos cefalosporínicos em ambientes aquáticos. Paralelamente, foram realizados testes de adsorção utilizando soluções de cefalosporina com concentração de 15 mg L⁻¹, variando o tempo de agitação entre 10 e 120 minutos. A cinética de adsorção foi avaliada com base nos modelos de pseudo-primeira ordem, pseudo-segunda ordem, Elovich e difusão intrapartícula. A adsorção foi analisada através de espectrometria UV-Vis, onde se identificou um pico de absorção característico a 240 nm.

Resultados: Os resultados indicaram que o modelo de pseudo-primeira ordem apresentou o coeficiente de determinação mais elevado (R² = 0,991), sugerindo que o mecanismo predominante é a adsorção física. Esta análise confirmou a capacidade da acácia em adsorver cefalosporinas, evidenciando o seu potencial como biosorvente.

Conclusão: Este estudo sublinha a relevância dos biosorventes, como a Acacia dealbata, no tratamento de poluentes da indústria farmacêutica. A utilização de materiais sustentáveis oferece uma solução promissora para o tratamento de águas, abrindo caminho para futuras aplicações no campo da biossorção.

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Estudos preliminares de Adsorventes Lenhocelulósicos para a Remoção de Cefalosporinas

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