Yazar "Chormey, Dotse Selali" seçeneğine göre listele

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    Biogenic synthesis of novel nanomaterials and their applications
    (Royal Soc Chemistry, 2023) Chormey, Dotse Selali; Zaman, Buse Tugba; Borahan Kustanto, Tuelay; Erarpat Bodur, Sezin; Bodur, Sueleyman; Tekin, Zeynep; Nejati, Omid
    Despite the many benefits derived from the unique features and practicality of nanoparticles, the release of their toxic by-products or products from the synthesis stage into the environment could negatively impact natural resources and organisms. The physical and chemical methods for nanoparticle synthesis involve high energy consumption and the use of hazardous chemicals, respectively, going against the principles of green chemistry. Biological methods of synthesis that rely on extracts from a broad range of natural plants, and microorganisms, such as fungi, bacteria, algae, and yeast, have emerged as viable alternatives to the physical and chemical methods. Nanoparticles synthesized through biogenic pathways are particularly useful for biological applications that have high concerns about contamination. Herein, we review the physical and chemical methods of nanoparticle synthesis and present a detailed overview of the biogenic methods used for the synthesis of different nanoparticles. The major points discussed in this study are the following: (1) the fundamentals of the physical and chemical methods of nanoparticle syntheses, (2) the use of different biological precursors (microorganisms and plant extracts) to synthesize gold, silver, selenium, iron, and other metal nanoparticles, and (3) the applications of biogenic nanoparticles in diverse fields of study, including the environment, health, material science, and analytical chemistry. Synthesis of nanoparticles of different shapes and sizes using biological precursors and their applications.
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    Deep eutectic solvents for the determination of endocrine disrupting chemicals
    (Elsevier, 2024) Chormey, Dotse Selali; Zaman, Buse Tugba; Kustanto, Tulay Borahan; Bodur, Sezin Erarpat; Bodur, Suleyman; Er, Elif Ozturk; Bakirdere, Sezgin
    The harmful effects of endocrine disrupting chemicals (EDCs) to humans and other organisms in the environment have been well established over the years, and more studies are ongoing to classify other chemicals that have the potential to alter or disrupt the regular function of the endocrine system. In addition to toxicological studies, analytical detection systems are progressively being improved to facilitate accurate determination of EDCs in biological, environmental and food samples. Recent microextraction methods have focused on the use of green chemicals that are safe for analytical applications, and present very low or no toxicity upon disposal. Deep eutectic solvents (DESs) have emerged as one of the viable alternatives to the conventional hazardous solvents, and their unique properties make them very useful in different applications. Notably, the use of renewable sources to prepare DESs leads to highly biodegradable products that mitigate negative ecological impacts. This review presents an overview of both organic and inorganic EDCs and their ramifications on human health. It also presents the fundamental principles of liquid phase and solid phase microextraction methods, and gives a comprehensive account of the use of DESs for the determination of EDCs in various samples.
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    Trace determination of nickel in water samples by slotted quartz tube-flame atomic absorption spectrometry after dispersive assisted simultaneous complexation and extraction strategy
    (Springer, 2018) Özzeybek, Gözde; Alacakoç, Bihter; Kocabaş, Mehmet Yusuf; Bakirdere, Emine Gülhan; Chormey, Dotse Selali; Bakirdere, Sezgin
    This study presents a new method for the determination of nickel in aqueous samples by slotted quartz tube-flame atomic absorption spectrometry (SQT-FAAS) after a dispersive assisted simultaneous complexation and extraction (DASCE) process. Synthesized ligand was directly dissolved in the extraction solvent to eliminate the complex formation step prior to the extraction. All parameters of the SQT-FAAS and DASCE method were systematically optimized to improve the detection power of nickel for trace determinations. Under the optimum experimental conditions, the optimized method (DASCE-SQT-FAAS) recorded 137-fold enhancement in detection power over the conventional FAAS. The limits of detection and quantification were determined to be 1.6 mu g/L and 5.2 mu g/L, respectively. The calibration plot was linear over a wide concentration range and the precision for replicate measurements was appreciably high. Nickel was not detected in five different water samples but spiked recovery tests for three samples yielded results that were close to 100%, confirming the method's accuracy and applicability to the matrices tested.
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    Trace element determination using mass spectrometry coupled detection methods
    (Elsevier b.v., 2025) Chormey, Dotse Selali; Er, Elif Öztürk; Bodur, Sezin Erarpat; Zaman, Buse Tuğba; Bodur, Süleyman; Kustanto, Tülay Borahan; Kayın, İnci; Bakırdere, Sezgin
    About half a century ago, trace elements in the environment were restricted at upper parts per billion levels due to limited information on their toxicological effects on humans and other organisms in the environment. In this present day, stricter restrictions are being enforced by several regulatory authorities to curb the continuous release of trace elements into the environment through anthropogenic activities that have resulted from the demand to meet the global population increase. The severity of health disorders related to trace elemental exposure from different sources and doses seem to overshadow their relevance for several biological functions. Thus, toxicological studies that elucidate the harmful effects of chemicals and help regulators to set limits of restriction require very sensitive analytical instruments that offer selectivity and specificity for accurate and precise determinations. Mass spectrometry is a unique technique that suits the purpose of identifying, confirming and quantifying elements that emanate from various chemical species. Inductively coupled plasma mass spectrometry is a superior analytical technique used for the simultaneous determination of trace elements in various samples. This superior technique is further augmented by solid phase and liquid phase microextraction methods, which help separate trace elements from complex matrices into clean, readable and enriched forms for the instrument.
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    Trace element determination using mass spectrometry coupled detection methods
    (Elsevier B.V., 2025) Chormey, Dotse Selali; Er, Elif Öztürk; Bodur, Sezin Erarpat; Zaman, Buse Tuğba; Bodur, Süleyman; Kustanto, Tülay Borahan; Kayın, İnci; Bakırdere, Sezgin
    About half a century ago, trace elements in the environment were restricted at upper parts per billion levels due to limited information on their toxicological effects on humans and other organisms in the environment. In this present day, stricter restrictions are being enforced by several regulatory authorities to curb the continuous release of trace elements into the environment through anthropogenic activities that have resulted from the demand to meet the global population increase. The severity of health disorders related to trace elemental exposure from different sources and doses seem to overshadow their relevance for several biological functions. Thus, toxicological studies that elucidate the harmful effects of chemicals and help regulators to set limits of restriction require very sensitive analytical instruments that offer selectivity and specificity for accurate and precise determinations. Mass spectrometry is a unique technique that suits the purpose of identifying, confirming and quantifying elements that emanate from various chemical species. Inductively coupled plasma mass spectrometry is a superior analytical technique used for the simultaneous determination of trace elements in various samples. This superior technique is further augmented by solid phase and liquid phase microextraction methods, which help separate trace elements from complex matrices into clean, readable and enriched forms for the instrument. © 2024 Elsevier B.V.