Katalaz Enzim Aktivite Ölçüm Yöntemleri: Literatürdeki Mevcut Yaklaşımlar, Karşılaştırmalar ve Yeni Perspektifler

Year 2026, Volume: 9 Issue: 2, 1204 - 1218, 16.03.2026

Meryem Sena Akkuş , Ceylan Bal

https://doi.org/10.47495/okufbed.1704381

https://izlik.org/JA64KP26CZ

Abstract

Katalaz enzimi, hidrojen peroksidi su ve oksijene parçalayarak oksidatif stresi düzenleyen kritik bir antioksidan enzimdir. Memeliler, bitkiler ve aerobik organizmalarda yaygın olarak bulunur ve özellikle eritrositler, karaciğer ve böbrekte yüksek konsantrasyonlarda yer alır. Tetramerik bir yapıya sahip olan katalazın NADPH bağlı formu, oksidatif inaktivasyona karşı korunmasını sağlamaktadır. Bu çalışmada, katalaz aktivitesini belirlemeye yönelik spektrofotometrik, kolorimetrik, elektroanalitik, titrimetrik, kemilüminesans ve jel bazlı yöntemler karşılaştırılmıştır. Her yöntemin avantajları, dezavantajları ve kullanım alanları detaylı şekilde değerlendirilmiş, daha hassas ve güvenilir ölçüm teknikleri geliştirmek için öneriler sunulmuştur. Ayrıca, yapay zeka ve makine öğrenmesi destekli analizlerin katalaz aktivitesi ölçümlerinde nasıl kullanılabileceği ele alınmıştır. Makine öğrenmesi tabanlı regresyon modellerinin büyük veri kümelerinden yararlanarak katalaz aktivitesini tahmin edebileceği ve ölçüm hassasiyetini artırabileceği öne sürülmüştür. Bu derleme, katalaz aktivite ölçüm yöntemlerinin mevcut durumunu kapsamlı bir şekilde inceleyerek gelecekteki çalışmalar için yeni perspektifler sunmaktadır.

Keywords

Katalaz , Katalaz ölçüm yöntemleri , Yapay zeka , Makine öğrenmesi

Catalase Enzyme Activity Measurement Methods: Current Approaches, Comparisons, and New Perspectives in the Literature

https://izlik.org/JA64KP26CZ

Abstract

Catalase is a critical antioxidant enzyme that regulates oxidative stress by breaking down hydrogen peroxide into water and oxygen. It is commonly found in mammals, plants, and aerobic organisms, with particularly high concentrations in erythrocytes, the liver, and kidneys. The NADPH-bound form of catalase, which has a tetrameric structure, protects the enzyme from oxidative inactivation. This study compared spectrophotometric, colorimetric, electroanalytical, titrimetric, chemiluminescence-based, and gel-based methods for determining catalase activity. Each method's advantages, disadvantages, and application areas were evaluated in detail, and suggestions were presented for developing more sensitive and reliable measurement techniques. In addition, the potential use of artificial intelligence and machine learning-supported analyses in measuring catalase activity was discussed. It was proposed that machine learning-based regression models could utilize large datasets to predict catalase activity and enhance measurement accuracy. This review comprehensively examines the current state of catalase activity measurement methods and offers new perspectives for future research.

Keywords

Catalase , Catalase measurement methods , Artificial intelligence , Machine learning

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