A review: Progress and trend advantage of dopamine electrochemical sensor

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Abdul Karim, M. Yasser, Ahyar Ahmad, Hasnah Natsir, Abdul Wahid Wahab, St. Fauziah, Paulina Taba, Irham Pratama, Rosalin, Arini Rajab, Andi Nur Fitriani Abubakar, Tri Widayati Putri, Rachmin Munadi, Ahmad Fudhail Majid, Arfiani Nur, Fadliah, Akhmad Rifai, Muallim Syahrir

2024 Journal of Electroanalytical Chemistry Vol. 959 Review Cited by 57 Quartile

Abstract

Dopamine is an important neurotransmitter in the human nervous system. Abnormal dopamine conditions can cause diseases such as Parkinson's, stimulating studies to develop electrochemical methods that are real time, sensitive, and selective compared with traditional methods. This review begins by exploring the various types of electrode modifications used in the development of dopamine sensors, such as the combination of enzymes, aptamers, inorganic materials and derivates, metal oxides, noble metals and molecularly imprinted polymers. Enzyme-based dopamine sensors use specific enzymes to recognize and detect dopamine with high specificity towards dopamine. Aptamer-based sensors employ DNA or RNA aptamers as recognition elements that selectively bind dopamine. MIP-based sensors utilize synthetic polymers imprinted with dopamine molecules to achieve selective recognition. The use of inorganic molecules such as graphene, noble metals, and metal oxides can enhance sensor performance by improving the sensitivity and stability of bioreceptors, with even inorganic materials like reduced graphene oxide (rGO) capable of serving as sole modifiers for electrochemical sensor modification. This review discusses the advantages and disadvantages of each sensor type and proposes future research directions, including optimization of sensor fabrication techniques and exploration of new nanomaterials to enhance the performance of electrochemical dopamine sensors. © 2024 Elsevier B.V.

Affiliations

Department of Chemistry, Hasanuddin University, South Sulawesi, Makassar, 90245, Indonesia; Department of Chemical Engineering, State Polytechnic of Ujung Pandang, South Sulawesi, Makassar, 90245, Indonesia; Department of Chemical Engineering, Fajar University, South Sulawesi, Makassar, 90231, Indonesia; Department of Environmental Management, Samarinda State Polytechnic of Agriculture, East Kalimantan, Samarinda, 75131, Indonesia; Department of Chemistry, Muhammadiyah University of Bulukumba, South Sulawesi, Bulukumba, 92513, Indonesia; Department of Fishery Products Technology, Institute of Maritime Technology and Business Balik Diwa, South Sulawesi, Makassar, 90245, Indonesia; Department of Chemistry, Islamic University of Makassar, South Sulawesi, Makassar, 90245, Indonesia; Department of Chemistry, Makassar State University, South Sulawesi, Makassar, 90222, Indonesia; Department of Mining Engineering, Trisakti University, Jakarta, 11450, Indonesia; Department of Chemistry, Alauddin State Islamic University, South Sulawesi, Makassar, 92118, Indonesia