Determination Of Metal Concentrations Research Articles

Divalent transition metal complexes with mixed of β-enaminone and N,O-donor ligands: synthesis, characterization and biological assessment

This study extensively describes the synthesizing and characterizing of new β-enaminone complexes derived from dimedone and amines coordinated with transition metals Fe(II), Co(II), Ni(II), and Cu(II), also two ligand's metformin (Met) and 8-hydroxyquinoline (8-hq). These were determined via FT-IR, 1H-NMR, electron and mass spectroscopy, molar electrical conductivity, thermal analysis (TGA, DTA and DSC) and characterized by metal content determination (%), magnetic susceptibility and elemental analysis (C.H.N.) and SEM technique. The measurements indicate that the complexes have six coordination numbers, where the β-enaminone is coordinated as tetradentate ligand through the two nitrogen atoms and the two oxygen atoms beside metformin is coordinated through the two nitrogen atoms and 8-hydroxyquinoline is coordinated by oxygen and nitrogen atoms as bidentate ligands. The conductance suggests that all complexes have electrolytic behavior, being conductive in a ratio of (1:2). SEM results revealed the presence of nanostructures on sample surfaces. The biological activity of the prepared ligands and complexes are studied in different concentrations for four types of bacteria Staphylococcus aureus has (+G) and Escherichia coli, Pseudomonas aeruginosa, Klebsiella have (-G), well as, the influence of the fungus. The ligands have disparate effectiveness while complexes have high effectiveness inhibiting the bacteria and fungus. KEY WORDS: Mixed ligand systems, Dimedone, β-Enaminone ligands, Transition metals, Biological application Bull. Chem. Soc. Ethiop. 2025, 39(1), 65-78. DOI: https://dx.doi.org/10.4314/bcse.v39i1.5

Antifungal Activity of Some New Binuclear Complexes

Three complexes of copper(II) and iron(II) with mixed ligands acetylacetonebis(thio-semicarbazone)- ABTSH2 and benzaldazine- BA have been prepared and characterized using different physico-chemical techniques including the determination of metal contents, mole-cular weight, measurement of molar conductivity, magnetic moment, molar refraction, infrared and electronic spectra. Accordingly, octahedral complexes having general formulaes [Cu2(ABTSH2)2(BA)2Cl2]Cl2 and [M2(ABTSH2)2(BA)2(SO4)2] {M= Cu(II) or (Fe(II)} have been proposed. The resulted complexes screened for antifungal activity in vitro against the citrus pathogen Aspergillus niger and Fusarium sp. which caused root rot of sugar and the beans pathogen Alternaria sp. All the complexes exhibited significant antifungal activities against these pathogens. The antifungal activity of these complexes were comparable with the standard fungicides in ethanol. The complex [Cu2(ABTSH2)2(BA)2Cl2]Cl2 had the best antifungal activity against Alternaria sp.

Escherichia coli alcohol dehydrogenase YahK is a protein that binds both iron and zinc.

Previous studies have highlighted the catalytic activity of Escherichia coli alcohol dehydrogenase YahK in the presence of coenzyme nicotinamide adenine dinucleotide (NAD) and metal zinc. Notably, competitive interaction between iron and zinc ligands has been shown to influence the catalytic efficiency of several key proteases. This study aims to unravel the intricate mechanisms underlying YahK's catalytic action, with a particular focus on the pivotal roles played by metal ions zinc and iron. The purified YahK protein from E. coli cells cultivated in LB medium was utilized to investigate its metal-binding properties through UV-visible absorption measurements and determination of metal content. Subsequently, the effects of excess zinc and iron on the metal-binding ability and alcohol dehydrogenase activity of the YahK protein were explored using M9 minimal medium. Furthermore, site-directed mutagenesis technology was employed to determine the iron-binding site location within the YahK protein. Polyacrylamide gel electrophoresis was conducted to examine the relationship between iron and zinc with respect to the YahK protein. The study confirmed the presence of iron and zinc in the YahK protein, with the zinc-bound form exhibiting enhanced catalytic activity in alcohol dehydrogenation reactions. Conversely, the presence of iron appears to play a pivotal role in maintaining overall stability of the YahK protein. Furthermore, experimental findings indicate that excessive zinc within M9 minimal medium can competitively bind to iron-binding sites on YahK, thereby augmenting its alcohol dehydrogenase activity. The dynamic binding of YahK to iron and zinc unveils its intricate regulatory mechanism as an alcohol dehydrogenase, thereby highlighting the possible physiological role of YahK in E. coli and its significance in governing cellular metabolic processes. This discovery provides a novel perspective for further investigating the specific impact of metal ion binding on YahK and E. coli cell metabolism.

Leaching a complex copper–cobalt oxide ore from Zebesha Mine in Zambia, a novel method

The study focused on leaching complex copper–cobalt oxide ore from Zebesha Mine in Zambia. The chemical analysis indicated the presence of cobalt, copper, nickel, manganese and iron as base metals. Copper is predominantly found in malachite and a small portion in heterogenite mineral along with cobalt, iron, manganese and nickel. The leaching process involved using solutions containing iron: ferrous sulphate, FeSO4·7H2O; ferrous ammonium sulphate, (NH4)2Fe(SO4)2·6H2O; and ferric sulphate, Fe2(SO4)3. The effects of temperature and salt concentrations were studied alongside metal content determination through titration-atomic absorption spectroscopy techniques. It was observed that the preferential dissolution of copper occurred with Fe2 (SO4)3 while temperatures above 70°C leaching with FeSO4·7H2O resulted in the recovery of over 80% of manganese and cobalt. This study suggests that ferrous containing lixiviants can effectively promote the manganese and cobalt dissolution but are not efficient for extracting copper. Furthermore, using Fe2(SO4)3 may allow for selective leaching of copper.

Determination of Heavy Metal Content in Imported and Local Red Meat in Northern Iraq (Erbil) Region

Determination of Heavy Metal Content in Imported and Local Red Meat in Northern Iraq (Erbil) Region

MCM-41 supported 2-aminothiophenol/Cu complex as a sustainable nanocatalyst for Suzuki coupling reaction

We have developed an innovative mesoporous nanocatalyst by carefully attaching a 2-aminothiophenol-Cu complex onto functionalized MCM-41. This straightforward synthesis process has yielded a versatile nanocatalyst known for its outstanding efficiency, recyclability, and enhanced stability. The structural integrity of the nanocatalyst was comprehensively analyzed using an array of techniques, including BET (Brunauer–Emmett–Teller) for surface area measurement, ICP (Inductively Coupled Plasma) for metal content determination, EDS (Energy-Dispersive X-ray Spectroscopy) for elemental mapping, XRD (X-ray Diffraction) for crystalline structure elucidation, SEM (Scanning Electron Microscopy), EMA (Elemental Mapping Analysis), TEM (Transmission Electron Microscopy), TGA (Thermogravimetric Analysis), FT-IR (Fourier Transform Infrared Spectroscopy), AFM (Atomic Force Microscopy), and CV (cyclic voltammetry). Subsequently, the catalytic properties of the newly developed MCM-41-CPTEO-2-aminothiophenol-Cu catalyst was evaluated in the synthesis of biphenyls, demonstrating outstanding yields through a Suzuki coupling reaction between phenylboronic acid and aryl halides. Importantly, this reaction was conducted in an environmentally friendly medium. Note the remarkable recyclability of the catalyst, proving its sustainability over six cycles with minimal loss in activity additionally hot filtration test was prepared to examine the stability of this nanocatalyst. This outstanding feature emphasizes the catalyst's potential for long-term, environmentally conscious catalytic applications.

Determination of Trace Heavy Metals Content of Various Herbal Drinks Marketed in Ilorin Metropolis, Nigeria

The study encompasses an evaluation of the health risk and hazard profiles of heavy metals contents in various herbal drinks (AGBO) products marketed in Ilorin metropolis, Nigeria. Twenty (20) herbal drinks samples from four (4) different study (saw-mil, Osere, Oja-oba and Oke-odo) areas were collected randomly, digested and analyzed. Zinc, Lead, Copper, Iron, Manganese, Cadmium, Chromium and Nickel were analyzed using Atomic Absorption Spectrometer. The results of this study indicated that most of the heavy metals (Zn, Pb, Cu and Mn) in the herbal drinks were below the WHO recommended permissible limits. Chromium (Cr) and Cadmium (Cd) are not detected in all of the herbal drinks analyzed. However, sample C2 and D2 among other analyzed herbal samples contained unsafe concentrations of iron (Fe) and nickel (Ni) that exceeded the WHO recommended permissible limits. From the health point of view, the EDIs value of all the herbal drinks are below the daily reference dose. The non-cancerous (HQ) and hazard index (HI) value of all the herbal samples are less than one (1). Based on the results obtained in this study, there would be a non-carcinogenic health risk and hazard effects to the people taking and consuming the herbal drinks marketed in all the study areas.

A Method for Quantitative Assessment of Metal Accumulation in the Human Body during Polymetallic Pollution of Urban Ecosystem Components

High metal concentrations in the body’s biological substrates often result from a persistent, cumulative impact of adverse environmental conditions. This article considers the quantitative composition of human biological substrates as an indicator of the state of urban ecosystem components. Assessing the accumulation of metals in the body by directly measuring their concentrations in biological substrates is a multi-step analytical procedure. Here, a quick-and-easy method for determining metal concentrations in biological substrates based on a neural network algorithm was introduced. A complex neural network model was developed to enable the determination of metal inputs from the air and food-water system without the need for invasive sampling of biomaterials or too difficult processing and analysis of the samples obtained. The model also proved to be feasible in solving the inverse problems associated with the determination of metal thresholds in various components of urban ecosystems.

Development and Assessment of a Nutritional Supplement Formulation for Diabetes Mellitus

Diabetes, a major global health issue, affects 424.9 million people worldwide, with a significant portion undiagnosed, leading to severe health and economic impacts. Effective management of diabetes includes dietary interventions, among which nutraceuticals play a crucial role. Nutraceuticals are food-derived compounds that offer health benefits, including disease prevention and treatment. This study focuses on the development of an antidiabetic nutraceutical instant soup powder formulated with ingredients like fenugreek seed, finger millet, tomato, curry leaves, garlic, black pepper, black salt, stevia, and oyster mushrooms.The raw materials were sourced from local markets and processed to create a fine powder mix. The soup powder’s physicochemical parameters, including pH, viscosity, moisture content, and ash levels, were measured. Nutritional analysis, sensory evaluation, and heavy metal content determination were conducted following standard protocols. The soup powder exhibited significant antimicrobial, antioxidant, and antidiabetic properties, demonstrating potential as a dietary supplement for diabetes management. The sensory evaluation indicated high acceptability among the panelists, highlighting the product’s feasibility for consumer use.

Integrated Assessment of Heavy Metal Contamination in Urban Road Dust: Implications for Human Health and Ecosystem Sustainability in Abeokuta, Nigeria

This research aims to comprehensively investigate the heavy metal contamination in road dust within the rapidly expanding urban area of Abeokuta, Nigeria. Focusing on potentially hazardous metals such as Cr, Co, As, Ni, Cu, Zn, Cd, Fe, and Pb, the study employs multivariate statistical techniques to identify sources, assess ecological and health hazards, and determine metal concentrations. Through the analysis of twenty road dust samples, variations in metal concentrations are observed, leading to the application of the geo-accumulation index, contamination factor, contamination degree, and pollution load index for contamination assessment. The results reveal varying degrees of contamination, with notable concentrations of Pb and Ni, indicating a deteriorating urban environment. Ecological risk assessments underscore potential threats to local flora and wildlife, while health risk evaluations emphasize urgent corrective actions needed, particularly for children exposed to heightened carcinogenic and non-carcinogenic hazards. Factor analysis and correlation studies unveil common anthropogenic origins for several metals, shedding light on the need for pollution mitigation techniques in the face of rapid urbanization and industrialization. The research contributes valuable insights to environmental and public health evaluations in the Abeokuta region, emphasizing the importance of informed decision-making for policymakers and the public.

Determination of Heavy Metal Contents in some Medicinal Plants from The Region of Oran from Algeria

Background: Some heavy metals found in our environment are toxic; once absorbed by plants, they build up in tissues and are phased out. Other heavy metals are trace elements needed for human health, but they can be toxic in excess concentrations. Objective: The purpose of this study is both to confirm the necessary metals' recognized medicinal virtues and to raise awareness of the presence of harmful non-essential metals that could harm humans and the environment. Methods: This study depicts a profile of existence of heavy metals (Zn, Cu, Cd, Pb, Fe) in some important herbal plants used in some parts of the country as a food condiment like (Moringa oleifera, Artemesia campestis, Nigella sativa, Asparagus stipularis, Sesamum indicum, Ruta montana, Rhamnus alaternus, Pistacia lentiscus using atomic absorption spectrophotometer. Results: The heavy metals in these medicinal plants were in the range of 0.38-0.56ppm of Zn, 0.00- 0.69 ppm of Cu, 0.13-0.16 ppm of Cd, 0.26-0.52 ppm of Pb, 1.10-8.89 ppm of Fe. Of the eight medicinal plants/products examined, the prescribed limits were respected. For each plant, a test sample of 2 grams of powder is mineralized. Each mineral is analyzed by injection. For each element, a calibration curve is generated. Assay with atomic absorption devices (lead, copper, cadmium, nickel, manganese) is carried out. The results are expressed in mg/L for different species. The highest value is lead. Copper content is present in various extracts and is considered a good source. Conclusion: The obtained results are promising for human health. The zinc contained in Moringa is very valuable. The presence of iron in the species Rhamnus alaternus confirms its use in traditional medicine as an anti-anemic.

Synthesis, characterization and antibacterial studies of ciprofloxaci-imines and their complexes with oxozirconium(IV), dioxomolybdenum(VI), and dioxotungsten(VI)

We synthesized and characterized ciprofloxacin-imine complexes, generated from ciprofloxacin and either 4-nitro-1,2-phenylenediamine (NO2PD) or 1,3-propanediamine (PD), in conjunction with zirconyl nitrate dihydrate, sodium molybdate dihydrate, and sodium tungstate dihydrate. Characterization involved numerous analytical methods, containing melting point determination, conductance dimensions, elemental analysis (CHN), metal content determination (%), infrared, electronic spectra, nuclear magnetic resonance, and mass spectrometry. Our findings reveal that the ligand as functions a tetra-dentate chelate binding to metal ions via azomethine and deprotonated carboxylate group. Additionally, the complexes and ligands were tested in contradiction of two types of bacteria (Staphylococcus aureus, Bacillus subtilis) and all prepared compounds showed good spectrum activity. KEY WORDS: 4-Nitro-1,2-phenylenediamine, Ciprofloxacin-imine, In-vitro antimicrobial activity, Zr complexes Bull. Chem. Soc. Ethiop. 2024, 38(4), 949-962. DOI: https://dx.doi.org/10.4314/bcse.v38i4.11

Synthesis, characterization, and antibacterial studies of some of first transition series metals and zinc complexes with mixed ligands of trimethoprim-isatin and nitrogen base

Complexes of mixed-ligand Schiff bases [trimetho-prim (TMP) with isatin] (L1) and nitrogen bases [2,2′-bipyridine (bipy)] (L2), [1,10-phenanthroline (phen) (L3)] with metal chlorides: M = Cr3+, Mn2+, Co2+, Ni2+, Cu2+, Zn2+ were prepared and characterized by metal content determination (%), FT-IR, electronic, nuclear magnetic resonance, mass spectroscopy, magnetic susceptibility, conductance measurements and elemental analysis (CHN). The bacterial activity of the ligands and their metal compounds was evaluated via various microorganisms. Infrared spectra of Schiff base showed an azomethine peak shifted in complexes that coincide synthesis and coordination of Schiff base through the nitrogen atom of azomethine C=N) and the oxygen atom of the carbonyl group of L1 with metal ions. L2, L3 (bipy, phen) coordinated through the di imine nitrogen atoms. Conductance dimensions suggested the non-conductance nature of all the compounds except Cr(III) complexes, this outcome fits in with the molar conductance value estimated for 1:1 electrolyte in DMF. Magnetic susceptibility analysis and electronic spectra indicated an octahedral geometry for all complexes. Biological study for prepared compounds have been evaluated towards pathogenic microbes Staphylococcus aureus and Bacillus subtilis. Some compounds have stronger antibacterial action than Schiff base towards tested microbes. KEY WORDS: Antimicrobial, Heterocyclic compounds, Schiff base, Trimethoprim drug, 2,2-Bipyridyl, 1,10-Phenanthroline Bull. Chem. Soc. Ethiop. 2024, 38(4), 1013-1025. DOI: https://dx.doi.org/10.4314/bcse.v38i4.16

Preparation of complex titanium-containing coagulants from large-scale mineral concentrates and their use in wastewater treatment

Relevance. Development of new, highly effective reagents for treatment of wastewater of various origins is a complex and extremely important task. An equally pressing issue remains the development of technologies for processing large-scale mineral products, which currently have not found an economically feasible technology for their processing and have received the status of “waste”. The development of a technology for producing reagents using waste as a raw material will not only have an economic effect but will also significantly minimize the level of negative impact on the environment and take a step towards the implementation of the Zero Waste concept. Aim. Development of technology for processing large-scale titanium-containing raw materials to obtain complex titanium-containing reagents and study of their effectiveness in wastewater treatment from various industries. Methods. To study the phase composition of the samples, the X-ray diffraction method was used, and the determination of metal content in acidic solutions and wastewater was carried out by atomic emission spectroscopy. Results and conclusions. The authors have proposed the technology for production of complex titanium-containing coagulants, which includes hydrometallurgical technology for sulfuric acid processing of large-capacity mineral raw materials – titanite. Aluminum hydroxide was introduced into the resulting solutions to adjust the chemical composition and neutralize free sulfuric acid. The resulting aluminum sulfate transforms into the most stable form of 18-aqueous crystalline hydrate, absorbing moisture from the solution, realizing chemical dehydration. The study of the composition of solid samples of coagulants showed that the predominant phase in the composition of the complex coagulant is aluminum sulfate, and the content of titanium compounds ranges from 1 to 14 wt %. It was established that by varying the ratio of mineral raw materials:sulfuric acid it is possible to vary the amount of modifying additive titanium compounds in the complex reagent. It was proven that the use of complex titanium-containing coagulants in wastewater treatment allows reducing the consumption of coagulants by 25–35%, increasing the efficiency of water purification, minimizing residual concentrations of pollutants, and also significantly increasing the rate of sedimentation of coagulation sludge in comparison with traditional sulfate aluminum.

LID Approach to Railway Track Drainage: Determination of Heavy Metal Content in the Embankment of Railway

Along with the increase in global pollution, every part of the urban system, including facilities for the transport of people and goods, is becoming increasingly interesting for the study. The first serious research into the impact of railway traffic on the environment appeared after the year 2000. So far, there have been few studies, the main shortcoming of which is a lack of understanding about pollutant migration. With this in mind, in this paper, an investigation and control of the railway track with regard to the presence, content and migration paths of heavy metals was provided. For the research purposes, X-ray fluorescence spectrometry and optical emission spectrometry with induced coupled plasma were used. It was found that the maximum allowable values were exceeded for cadmium, cobalt, copper, zinc, nickel, vanadium, barium, chromium and iron. In the course of determining the amount of these elements in the railway track, there was also evidence of significant metal infiltration into the lower layers. This indicated the ability of heavy metals to migrate, even through mechanically compacted soil. Detailed knowledge of these issues is of huge importance, which enables the selection of adequate techniques to prevent the migration of heavy metals into the lower layers of the ground and the surrounding soil, among which the elements of Low Impact Development technology stand out in recent years, which could find a very wide and effective application in railway engineering.

Detecting changes in industrial pollution by analyzing heavy metal concentrations in tree-ring wood from Romanian conifer forests

The impact of air pollution on forests, especially in urban areas, has been increasingly discussed recently. Many pollutants, including heavy metals, are released into the atmosphere from various sources, such as mining, non-ferrous metal processing plants, and fossil fuel combustion. These pollutants can adversely affect not only tree growth but also other species, including humans.This study compared the concentrations of several elements in tree-ring wood from two conifer species (Silver fir, Abies alba; Norway spruce, Picea abies) growing in polluted and unpolluted areas. Two regions in northern Romania (Bicaz and Tarnița) that were subjected to historical pollution changes were selected. Two chemical analyses were used: inductively coupled plasma mass spectrometry (ICP-MS) and X-ray fluorescence spectrometry (XRF).The silver fir trees from the intensively polluted area in the Tarnița region were negatively impacted by industrial pollution: the Mn concentrations were, on average, three times higher in polluted areas than in unpolluted areas (ca. 30 vs. 10 mg kg−1). This finding was consistent for both ICP-MS and XRF analyses. However, in Norway spruce, this difference was found only in the XRF data, which detected Mn concentrations seven times higher in trees from polluted areas than those from unpolluted areas (ca. 700 vs. 100 mg kg−1). In the Tarnița region, Norway spruce accumulated more heavy metals than silver fir, but the most pronounced differences between polluted and unpolluted areas were found in silver fir.The two analytical methods are commonly used to determine metal concentrations in wood, and they complement each other, with ICP-MS having a low detection limit for some elements and XRF having higher detection limits and better accuracy. Each method has its advantages and disadvantages, and the optimal method depends on many factors, such as the type of heavy metal analyzed, its concentration in wood, sample type, cost, analysis time, and sample preparation.

Direct elemental analysis of plant oils by inductively coupled plasma mass spectrometry: Simple sample dilution combined with oxygen introduction into the plasma

Assessment of trace metal concentrations in plant oils has been considered a crucial quality control marker for potential health risks, oil flavour, and oxidative stability. A straightforward inductively coupled plasma mass spectrometry (ICP-MS) methodology was developed and validated through introduction of argon:oxygen gas mixture into plasma, allowing for a direct elemental analysis of organic matrices. This approach offers the advantage of a simple one-step preparation of plant oil samples with negligible contamination risks. The complete solubilization of the oil matrix enables the determination of total metal content from a single test tube with low dilution factor of 5. The modified plasma conditions resulted in the development of a robust and accurate ICP-MS method providing limits of detection at sub ng·g−1 levels. The ICP-MS method allowed the determination of trace levels of Ba, Cd, Cu, Fe, Mn, Pb, Sn, V, and Zn in olive, sunflower and rapeseed oils.

Atmospheric air pollution of a mining town in the Kuzbass region by toxic metals

The paper analyses the results of active biomonitoring of atmospheric air pollution in the mining town of the Kuzbass region by the most toxic metals. The epiphytic moss Pylaisia polyantha (Hedw.) B. S. G. was used as a bioindicators; determination of metal content in moss samples was carried out using neutron activation analysis and atomic emission spectrometry methods. Based on the results of the study, spatial distributions for pollution levels of the most toxic metals were plotted and their sources were identified.

Evaluation of a tea bag formulation of Tapinanthus bangwensis (Engl. and K. Krause) Danser leaves, meant for the management of diabetes

The incorporation of traditional medicine into the mainstream health care delivery system particularly in some developing countries such as Ghana has resulted in reliable access to herbal medicines and their safe use. This has also led to a surge in the search for herbal alternatives, reformulation, and development of herbal medications in treating and managing diseases such as diabetes. Currently, the surging price of orthodox antidiabetics and their reported adverse effects from long term use has contributed to many Ghanaians switching to the use of phytomedicines as alternatives. The aim of this study is to formulate tea from the leaves of Tapinanthus bangwensis, family Loranthaceae to serve as an additional remedy for the management of diabetes.For standardization, quality control, and authentication of the formulation, FTIR, and HPLC analysis were conducted. The safety profile of the tea via determination of median lethal dose (LD50), microbial load, essential elements and toxic metal contents were also assessed. In addition, the pH, uniformity of mass, total water extractive and optimization of the extraction method were also investigated.The FTIR showed the presence of alcohols, esters, phenols and aromatic compounds. The HPLC fingerprint also showed 23 peaks with the highest peak having a retention time of 15.4 min. The extract also recorded a pH of 7.43 ± 0.02 at 26.1 °C and total water extractive of 39.37 ± 0.05 %w/w. The tea passed the uniformity of mass test with an average net mass of 3.0 ± 0.02 g. Optimum extraction of the tea was realised with 250 mL of freshly boiled water. The formulated tea was found to be safe since the determined LD50 was 50 times more than the daily dose. The microbial load, elemental and toxic metal contents were also within acceptable limits.This study has shown the possibility of introducing this tea at a safe dose as an additional herbal remedy for the management of diabetes.

Torrefaction of combustible construction and demolition waste: Evolution of fuel performance, heavy metal migration and combustion characteristics

Combustible construction solid wastes (CSW) derived from construction and demolition (C&D) wastes is an important part for waste-to-energy system. Torrefaction experiment of five CSW components involving plastic (PL), wood (WD), textile (TX), paper and board (PB), and rubber (RB) were conducted in a fixed-bed reactor at torrefaction temperature of 200–400 °C and holding time of 30 min. Fuel properties and heavy metal migration of CSW components via torrefaction are characterized by proximate analysis, ultimate analysis, caloric value determination, and the determination of heavy metal contents in solid, liquid and gas products. Combustion characteristics of CSW components and their torrefied solid products were evaluated by TG-FTIR method. The obtained results indicated that torrefaction has a significant influence on volatile matter, fixed carbon, calorific value, and H/C and O/C molar ratios of CSW components. The ash content in high ash CSW components increases and energy yield decreases significantly when torrefaction temperature is larger than 250 °C. Heavy metals of Zn, Pb, Cu and Mn in CSW components is partly migrated into the liquid products, but Hg and As are almost entirely present in the liquid products at different torrefaction temperatures. The combustible index and burnout index of PL, WD, PB and RB decrease gradually when torrefaction temperature is more than 250 °C, and the lower yields of SO2, NO, HCl, CH4 and CO of torrefied CSW are achieved at torrefaction temperature of 250 °C. The optimum torrefaction temperature of 250 °C is proposed for improving fuel properties, heavy metal migration and combustion characteristics of CSW components.