scholarly journals Effects of Various Precipitants on Iron Removal from a Zinc Concentrate Pressure Leaching Solution

Minerals ◽  
2022 ◽  
Vol 12 (1) ◽  
pp. 84
Author(s):  
Claudio A. Leiva ◽  
María E. Gálvez ◽  
Gerardo E. Fuentes ◽  
Claudio A. Acuña ◽  
Jannan A. Alcota
Keyword(s):  
Iron Concentration ◽  
High Viscosity ◽  
Ease Of Use ◽  
Iron Removal ◽  
Pressure Leaching ◽  
Zinc Recovery ◽  
Autoclave Leaching ◽  
Environmentally Friendly Process ◽  
Filtration Stage ◽  
Zinc Concentrate

Autoclave leaching of zinc concentrate (Sphalerite) is an environmentally friendly process compared to roasting, which discharges pollutants into the atmosphere. Due to the amount of iron in the final product, a study is proposed to evaluate different reagents for eliminating iron from the autoclave outcome, minimizing Zn losses. The colloid formation, zinc losses, iron removal, phase separation stage characteristics (sedimentation and filtering), and reagent costs were used to evaluate six-iron precipitating reagents: CaO, Na2CO3, CaCO3, NaOH, MgO, and Ca(OH)2. CaO shows 99.5% iron removal and 87% zinc recovery. Although CaO was one of the reagents with significant zinc recovery, it presented operational difficulties in the filtration stage due to the high viscosity of the mixtures. Finally, Ca(OH)2 is the reagent recommended due to its ease of use, zinc yield recovery, electrowinning efficiency, and iron precipitate filtration rate. Zinc recovery was above 80%, while the iron concentration in the solution was below 50 ppm.

scholarly journals Critical importance of pH and collector type on the flotation of sphalerite and galena from a low-grade lead–zinc ore

2021 ◽  
Vol 11 (1) ◽  
Author(s):  
Abdolrahim Foroutan ◽  
Majid Abbas Zadeh Haji Abadi ◽  
Yaser Kianinia ◽  
Mahdi Ghadiri
Keyword(s):  
Iron Ore ◽  
Low Grade ◽  
Zinc Recovery ◽  
Flotation Process ◽  
Ph Values ◽  
Lead And Zinc ◽  
Optimum Ph ◽  
Iron And Zinc ◽  
Lead Zinc ◽  
Zinc Concentrate

AbstractCollector type and pulp pH play an important role in the lead–zinc ore flotation process. In the current study, the effect of pulp pH and the collector type parameters on the galena and sphalerite flotation from a complex lead–zinc–iron ore was investigated. The ethyl xanthate and Aero 3418 collectors were used for lead flotation and Aero 3477 and amyl xanthate for zinc flotation. It was found that maximum lead grade could be achieved by using Aero 3418 as collector at pH 8. Also, iron and zinc recoveries and grades were increased in the lead concentrate at lower pH which caused zinc recovery reduction in the zinc concentrate and decrease the lead grade concentrate. Furthermore, the results showed that the maximum zinc grade and recovery of 42.9% and 76.7% were achieved at pH 6 in the presence of Aero 3477 as collector. For both collectors at pH 5, Zinc recovery was increased around 2–3%; however, the iron recovery was also increased at this pH which reduced the zinc concentrate quality. Finally, pH 8 and pH 6 were selected as optimum pH values for lead and zinc flotation circuits, respectively.

Optimization of Kaolin Bioleaching by Aspergillus niger

2007 ◽  
Vol 20-21 ◽  
pp. 115-118 ◽  
Author(s):  
M. Ranjbar ◽  
E. Aghaie ◽  
M.R. Hosseini ◽  
Mohammad Pazouki ◽  
F. Ghavipanjeh
Keyword(s):  
Aspergillus Niger ◽  
Ph Value ◽  
Iron Concentration ◽  
Iron Removal ◽  
Pistachio Shell ◽  
Dissolved Iron ◽  
Initial Ph ◽  
Negative Effect ◽  
Concentration Changes ◽  
Central Composite

In this paper, a central composite design was applied to optimize the bioleaching of iron from a kaolin sample containing 2.2% iron impurity by Aspergillus niger isolated from pistachio shell. The strains were inoculated into 500 ml flasks containing 100 ml media consisted of (g/l): sucrose 120; NH4NO3 0.45; KH2PO4 0.1; MgSO4.7H2O 0.3; FeSO4.7H2O 10-4; ZnSO4.7H2O 25×10- 5. The effects of initial pH, sugar and spore concentrations on iron removal extent were investigated. The two-level factorial design points were pH 2 and 5, sugar conc. 70 g/l and 130 g/l, spore conc. 9×107 and 35×107 spores/l. Also, the increase of dissolved iron, oxalic acid concentration, changes in pH value, and sugar concentration were registered. Consequently, after 10 days, the iron concentration of the best condition reached to 179.3 ppm that means 38.8% of the total iron content is removed. Furthermore, the data analysis showed that all the factors are significant, and the iron removal extent increases by increasing the initial pH to 4.4, sucrose content to 93.8 g/l, and spore concentration to 305.5 spores/μl, but further increase in each factor value has negative effect on the response.

Exjade® Reduces Cardiac Iron Burden in Chronically Transfused β-Thalassemia Patients: An MRI T2* Study.

Blood ◽  
2007 ◽  
Vol 110 (11) ◽  
pp. 2781-2781 ◽  
Author(s):  
J. Wood ◽  
A.A. Thompson ◽  
C. Paley ◽  
B. Kang ◽  
P. Giardina ◽  
...  
Keyword(s):  
Ejection Fraction ◽  
Iron Concentration ◽  
Iron Chelation ◽  
Left Ventricular ◽  
Iron Removal ◽  
Left Ventricular Ejection ◽  
Liver Iron ◽  
Ventricular Ejection Fraction ◽  
Cardiac Iron ◽  
The Mean

Abstract Introduction: Despite the routine use of iron chelation therapy, cardiac iron overload results in cardiomyopathy, congestive heart failure and death in approximately 71% of pts with β-thalassemia. Recent MRI studies suggest that the kinetics of cardiac iron uptake and elimination differ from that of liver. Furthermore, different chelators appear to exhibit unique profiles of relative heart and liver iron removal. Deferasirox (DFX; Exjade®) is a once-daily oral iron chelator with demonstrated efficacy in reducing liver iron. In addition, preclinical and single-institution clinical studies have demonstrated cardiac iron removal. This study is a prospective, single-arm multi-institutional trial designed to evaluate the effect of DFX on cardiac iron in pts with β-thalassemia major. Here, we report preliminary results from the first 15 pts who completed 6 months of treatment. Methods: This ongoing study will enroll 30 pts at 4 US centers. DFX is administered at 30–40 mg/kg/day for 18 months. Entry criteria include MRI evidence of cardiac iron (T2* <20 ms) and normal left ventricular ejection fraction (LVEF ≥56%). Serum ferritin is assessed monthly and MRI assessments for liver iron concentration (LIC), cardiac T2* and LVEF are assessed every 6 months. Labile plasma iron (LPI), serum creatinine, biochemical and hematological status are being monitored. Results: At the time of this analysis, 15 of 17 pts had 6 months of evaluation; all were dosed at 30 mg/kg/day. One of the excluded pts was found ineligible (LVEF <56% at baseline) and the other developed cardiac failure prior to 6 months and was switched to continuous DFO (deferoxamine). This pt had markedly elevated cardiac iron (T2*=1.8 ms) at enrollment. All results are reported as mean±SEM (range) unless otherwise stated. Baseline: All 15 evaluable pts (3 male, 12 female; aged 10–43 years) received ≥150 lifetime transfusions. Ferritin was 4927±987 ng/mL (395–10751; n=12). Cardiac T2* was 9.8±1.13 ms (5.0–16.1), LIC was 16.6±4.27 mg/g dw (3.6–62.3) and ejection fraction was 61.2±1.83%. LPI was 0.72±0.28 μmol/L (n=11) and 33% of pts started with abnormal LPI (≥0.5 μmol/L). 6 Month results: At 6 months, the mean decrease in ferritin was 516 ng/mL; 14 of 15 (93%) pts had decreases in hepatic and cardiac iron. The mean reductions in cardiac and hepatic iron were 17.8% (P=0.0136) and 27.0% (P=0.0027), respectively (Figure). There was no change in LVEF by MRI. All patients had normal LPI at 6 months; for pts with abnormal LPI at baseline, the mean LPI dropped from 1.6±0.3 to 0.26±0.1 μmol/L (P=0.003). No pts developed creatinine >upper limit of normal. Four pts had abnormal transaminases on ≥2 occasions but all 4 were abnormal at baseline. Conclusions: The 30 mg/kg/day dose was well tolerated and led to negative cardiac and liver iron balance in 93% of pts. These results are encouraging given this heavily iron-overloaded and heavily transfused population of β-thalassemia pts. Ongoing assessments over 12 and 18 months will elucidate if DFX continues to improve cardiac iron burden and maintain/improve cardiac function in severely iron-overloaded pts. Figure Figure

Modeling Combination Chelation Regimes To Optimize Cellular Iron Removal and Explore Mechanisms Of Enhanced Chelation

Blood ◽  
2013 ◽  
Vol 122 (21) ◽  
pp. 2200-2200
Author(s):  
Evangelia Vlachodimitropoulou ◽  
Garbowski Maciej ◽  
John B Porter
Keyword(s):  
Iron Concentration ◽  
Dual Therapy ◽  
Iron Chelator ◽  
Iron Removal ◽  
Intracellular Iron ◽  
Iron Storage ◽  
Synergy Index ◽  
Cellular Iron ◽  
Low Concentrations ◽  
Oral Chelators

Abstract Introduction Monotherapy with clinically available chelators, namely deferoxaime (DFO), deferasirox (DFX) or deferiprone (DFP) is effective but often slow and suboptimal. Combinations of DFO with DFP have been used clinically to enhance cellular iron mobilization but the conditions under which this occurs have not been studied systematically. With the emergence of DFX, the possibility exists to combine this with either DFO or DFP to enhance chelation. We have developed a system to study the optimal concentrations and times of exposure to these chelators, alone or in combination for maximising cellular iron removal. Isobol modeling has been used to determine whether interaction is additive or synergistic. The demonstration of synergy would imply the primary chelator acting as a ‘sink’ for iron chelated and donated to this sink by low concentrations of a secondary ‘shuttle’ chelator as shown in plasma (Evans et al. TransL. Res, 2010). Methods Human hepatocellular carcinoma (HuH-7) cells were chosen as hepatocytes are the major cell of iron storage in iron overload. Iron concentration was determined using the ferRozine (Riemer et al. Anal Biochem. 2004). A threefold increase of intracellular iron compared to control was obtained by serially treating cells with 10% FBS RPMI media. The cells were then exposed to iron chelator then lysed and intracellular iron concentration determined via the ferrozine assay, normalized against protein content. Cell viability was assessed using 0.4% Trypan blue as well as Acridine Orange /Propidium Iodide and was consistently > 98%. Isobolograms were constructed (Tallarida et al, Pharmacol Ther, 2010) as well as a the synergy index (QUOTE 1-1/R) x 100 (%), where R = difference of areas between the line of additivity and the curve of synergy on the isobologram. This index represents how much of the obtained effect exceeds that expected by additivity of two chelators. Results Monotherapy with DFP, DFX or DFO at clinically relevant concentrations of 1 to 30µM iron binding equivalents (IBE), induced both dose and time dependent cellular iron removal. Dual therapy combinations of all 3 chelators enhanced iron removal at 4, 8 and 12 hours. At 4 hours of incubation, whereas 10µM DFO alone had no demonstrable effect on cellular iron removal, addition of DFP at as little as 1µM IBE increased cellular iron removal. Table 1 shows examples of cellular iron removal at specimen chelator concentrations alone or in combination at 8h. The combination of DFX with DFO, DFX with DFP and DFP with DFO all resulted in enhanced cellular iron removal. The combination of DFP and DFX was the most effective. Isobol plot analysis from multiple chelator concentrations demonstrated synergy for all pairs at 4 and 8 hours of exposure. The derived synergy index at 8h indicates that when DFX and DFO are combined, 49% of the chelation effect is due to synergy in this system and 51% in the case of DFP and DFO combination. Most interestingly, the synergistic effect is even greater, in the case of the two oral chelators DFP and DFX when in combination (59%). Figure 1. Conclusion Remarkably low concentrations of a second chelator are required to enhance cellular iron removal by the primary chelator. Isobol analysis shows synergy rather than additivity as the mechanism for enhanced chelation for all 3 combinations, implying a ‘shuttle’ and ‘sink’ effect. Interestingly, the combination of two oral chelators DFP and DFX showed the most marked enhancement of cellular iron removal, without cellular toxicity, suggesting a potentially powerful therapeutic approach, provided this is also well tolerated clinically. The long plasma half life of once daily oral DFX will allow a continuous ‘sink’ for iron shuttled by the shorter acting DFP. Line of Additivity Curve of Synergy below the line Disclosures: Porter: Novartis: Consultancy, Honoraria, Research Funding; Shire: Consultancy, Honoraria; Celgene: Consultancy.

Agreement Between R2 and R2* Liver Iron Estimates Is Independent of the Type of Iron Removal Therapy: Results from the Twitch Trial

Blood ◽  
2016 ◽  
Vol 128 (22) ◽  
pp. 1274-1274 ◽  
Author(s):  
John C Wood ◽  
Tim St Pierre ◽  
Banu Aygun ◽  
Nicole Mortier ◽  
William H Schultz ◽  
...  
Keyword(s):  
Research Funding ◽  
Observation Interval ◽  
Geometric Mean ◽  
Iron Concentration ◽  
Iron Removal ◽  
Secondary Outcome ◽  
Limits Of Agreement ◽  
Perfect Agreement ◽  
Liver Iron ◽  
Measurement Variability

Abstract Introduction: TCD with Transfusions Changing toHydroxyurea (TWiTCH Clinical Trials.gov NCT01425307), an NHLBI-sponsored multicenter trial, compared transfusion pluschelation (Standard Arm) tohydroxyurea (HU) plus phlebotomy (Alternative Arm) in children with sickle cell disease at high risk for stroke. Alternative arm patients underwent serial phlebotomy (10mL/kg, maximum 500mL) every 4 weeks after reaching maximal tolerated dose (MTD) of HU and discontinuing transfusions. Changes in liver iron concentration (dLIC), measured as mg Fe per gram dry weight liver, by both MRI R2 (FerriScan) and R2* were key secondary outcome measures. R2 and R2* are two, different MRI techniques that exploit the magnetic properties of tissue iron to estimate iron concentration. We previously reported significant differences between the two approaches at the baselinetimepoint. The purpose of this investigation was to determine the limits of agreement between measurements ofdLIC over a period of one year by R2 and R2* methods in both arms of the study. Methods: MRI R2 and R2* data were collected prior to randomization, and after 1 year (midpoint) and 2 years of therapy (study exit). dLIC between baseline to midpoint and midpoint to study completion was calculated for both R2 and R2* LIC values. Since LIC measurement variability increases with iron burden, each dLIC pair (R2 and R2*) were normalized to the patients iron burden at the start of the observation interval. That is, dLIC from baseline to midpoint was normalized to baseline LIC, while dLIC from midpoint to study end was normalized to midpoint LIC. The geometric mean of LICR2 and LICR2* was used to represent the baseline and midpoint LIC. Bland Altman analysis was performed on measurements of the percent change of dLICR2 and dLICR2* to determine the limits of agreement between the two techniques. Results: R2 measurements were performed in 104 patients at baseline, 94 at midpoint and 99 at study end, while R2* measurements were performed in 101, 87, and 89 patients, respectively. However, missing data limited Bland Altman comparisons ofdLIC to 74 patients between baseline to midpoint and 69 patients from midpoint to study end. Figure 1 (left) plots the measureddLIC using R2 (vertical axis) against the measureddLIC change by R2* (horizontal axis) for the Standard Arm participants. Dots represent LIC change over the first year and open circles represent LIC changes over the second year. The dotted line represents perfect agreement. Figure 1 (right) demonstrates the corresponding relationship for the patients in the Alternative Arm. Although the alternative arm appears to have greater disagreement, this represents an artifactcause by the transient increases in LIC that occurred as patients bridged from standard to alternative therapy. Iron chelationwas stopped when patients began hydroxyureabut patients required an overlap period of transfusions for stroke prophylaxis. Figure 2 demonstrates the difference in dLIC measured by R2 and R2*, expressed as a percentage of starting LIC, plotted against the starting LIC value. The standard arm (open circles) and alternative arms (dots) completely overlap. 95% limits of agreement between the two measures ofdLIC were -45.7% to 63.7% (light lines). At LIC values > 8.3 mg/g,dLIC predicted by R2 was larger than predicted by R2*, while the converse was true for LIC values below 8.3 mg/g, similar to our published baseline findings for LIC measurements. Conclusions: LIC by R2 and R2* tracked one another closely over time in patients in both study arms. These data indicate that either technique can be used with confidence to monitor patients on iron removal therapy (chelation or phlebotomy), but that the techniques should not be interchanged. Figure 1 Figure 1. Figure 2 Figure 2. Disclosures Wood: Vifor: Consultancy; Ionis Pharmaceuticals: Consultancy; Vifor: Consultancy; Biomed Informatics: Consultancy; World Care Clinical: Consultancy; Ionis Pharmaceuticals: Consultancy; World Care Clinical: Consultancy; AMAG: Consultancy; AMAG: Consultancy; Celgene: Consultancy; Celgene: Consultancy; Biomed Informatics: Consultancy; Apopharma: Consultancy; Apopharma: Consultancy. St Pierre:Resonance Health: Consultancy, Equity Ownership. Piccone:Novartis: Other: Speaker. Hankins:Novartis: Research Funding. Rogers:Apopharma: Consultancy. Ware:Bayer Pharmaceuticals: Consultancy; Global Blood Therapeutics: Consultancy; Biomedomics: Research Funding; Addmedica: Research Funding; Nova Laboratories: Consultancy; Bristol Myers Squibb: Research Funding.

Sodium Lingo-Sulfonate and Sodium Dodecyl-Sulfate Mixtures Influence on Zinc Concentrate Pressure Leaching and Zinc Electro-Winning

2020 ◽  
Vol 299 ◽  
pp. 1121-1127
Author(s):  
E.B. Kolmachikhina ◽  
E.A. Ryzhkova ◽  
D.V. Dmitrieva
Keyword(s):  
High Temperature ◽  
Sodium Dodecyl Sulfate ◽  
Current Efficiency ◽  
Sodium Dodecyl ◽  
Pressure Leaching ◽  
Leaching Tests ◽  
Zinc Extraction ◽  
Zinc Surface ◽  
Dodecyl Sulfate ◽  
Zinc Concentrate

This paper is describing an investigation of sodium lingo-sulfonate and sodium dodecyl-sulfate mixtures influence on zinc concentrates high temperature oxidative pressure leaching and zinc electro-winning. For this purpose, surfactants concentration at leaching tests was varied from 200 to 800 mg∙l-1. It was established that the maximum zinc extraction (99 %) at leaching was achieved in the presence of mixture containing 800 mg∙l-1 lignosulfonate and 200 mg∙l-1 sodium dodecyl-sulfate. Therefore, this mixture can be recommended for high temperature oxidative pressure leaching of zinc concentrates. Sulfur-sulfide pellets formation also was observed at a low lingo-sulfonate concentration (200 mg∙l-1) in a mixture with sodium dodecyl-sulfate. This phenomenon can lead to emergency shut down of autoclave. It was observed that the mixture usage of 800 mg∙l-1 lignosulfonate and 200 mg∙l-1 sodium dodecyl-sulfate had no significant impact on zinc current efficiency, it was in the rage of 92-93 %. The mixture usage of 200 mg∙l-1 lignosulfonate and 600 mg∙l-1 sodium dodecyl-sulfate allowed to increase current efficiency up to 95 %. Increasing sodium dodecyl-sulfate concentration in mixtures with lignosulfonates leads to decrease of current efficiency, to formation of deep pores and defects on cathode zinc surface.

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