Published Journal Articles
2020
Removal of Organic Dyes by Using Cellulose-Chitosan-Nanowires Hybrid Composition Beads
2020-07
Materials Science Forum (Issue : 16629752) (Volume : 1002)
Organic dyes are mostly used in textile, paper, plastic, and other industries. These industries can be toxic and harmful to environment and human. Adsorption is the most efficient method to control wastewater that contains dyes. Cellulose-Chitosan beads was mainly used in the adsorption. To increase and enhance the organic dyes removal capacity of these beads, titanium dioxide nanowires (TiO2Nw) as used to achieve novel Cs-Cell-nanowires hybrid composites. Ultralong hydroxyapatite nanowires was prepared and used to enhance the mechanical and thermal properties of beads. On the other hand, the beads composition was prepared with spherical white shape. Internal structure of beads and other composition were studied by using Attenuated Total Reflectance (ATR) spectroscopy, scanning electron microscopy (SEM), lazer diffraction (LD), thermal analysis (TG, DSC, DTG, and DTA). The beads are tested with five different organic dyes which include Methyl blue (MB), Acid alizarin Black (AAB) as cationic dyes, and Methyl orang (MO), Methyl red (MR) and Eriochrome black T (EBT) as anionic dyes. The results indicate that the beads have the ability to remove MB, EBT,AAB but do not have the ability to remove MO and MR. So, the Cell-CS-HAPNw-TiO2Nw beads can be considered as the promising adsorption for MB, EBT, and AAB from aqueous solutions.
Synthesis of some 2-Pyridones by Application of L-L Phase Transfer Catalysis Method
2020-03
Materials Science Forum (Issue : 16629752) (Volume : 1002)
Phase-transfer catalysis P.T.C is one of the most widely used techniques in the preparation of a wide range of compounds not only in organic chemistry but also a broadly useful in several other areas of chemistry. There have been extensive studies that have been used to synthesize many compounds that are biologically important with highly efficient and the percentage of the product and purity are high with perfect time. In this study, a number of chalcones were prepared and reacted with phenoxy acetamide, 4-methyl phenoxy acetamide and phenyl mercapto acetamide for the preparation of 2–pyridones compounds under phase transfer catalysis conditions. The reaction mechanism and the structure of the resulting compounds were determined using physical analysis methods IR and 1H-NMR. 13C-NMR was used to measure some compounds.
2019
Saccharine based carbonyl multi-walled carbon nanotubes: novel modification, characterization and its ability for removing Cd(II) and Cu(II) from soil and environmental water samples
2019-10
Journal of Physics Conference Series (Issue : 1294) (Volume : 5)
This research highlights the chemical modification of one of the carbon nanostructures (multi-walled carbon nanotubes-COOH) with an artificial sweetener (saccharine) to synthesize a highly efficient absorbent material (MWCNTs-CO-Sac). This material was thereafter used to the packing column in solid phase extraction of cadmium and copper divalent ions from real samples. This nano-adsorbent was diagnosed with different techniques: infrared spectroscopy (FTIR), Thermogravimetry (TG), Differential thermal analysis (DTA), powder X-ray diffraction (PXRD), energy-dispersive X-ray spectroscopy (EDX), Particle size distribution (PSD) and scanning electron microscopy (SEM). The effect of pH, sample and eluent flow rates, volume, type and concentration of eluent, volume of sample and interfering ions were studied to achieve the optimal conditions for solid phase extraction of Cd(II) and Cu(II) based on the inductively coupled plasma-optical emission spectrometry (ICP-OES). Moreover, the preconcentration factors were calculated to be 75. The results of a limit of detection (LOD) 0.07 μgL-1 and 0.09 μgL-1 for Cd(II) and Cu(II) respectively. The relative standard deviation (RSD %) of this study was 0.45% for Cd(II) and 0.51% for Cu(II). The optimized method was applied to soil and environmental water samples.
Extracting Cellulose Fibers from Rice Husks to Prepare a pH Sensitive Hydrogel with Sodium Alginate
2019-07
Recent Researches in Earth and Environmental Sciences/Springer, Cham
In this paper, pH-sensitive hydrogels were prepared and developed from cellulose fibers extracted from rice husks with sodium alginate by using a double cross-linker. Cellulose fibers extraction process was carried out by alkaline and bleaching treatment. Cellulose fibers were used in variable quantities to investigate their effects on swelling degree. The resulted hydrogels showed a very strong swelling (1785-2718%) in phosphate buffer solution (pH 7), good swelling (776-1195%) in pH 10, and less swelling (81-124%) in pH 4. All of these swelling degrees and more properties of the resulted cellulose fibers and hydrogels were tested and evaluated via some techniques like Infrared spectroscopy (ATR), thermal analysis (TG, DTG, DSC, and DTA), and Scanning electron microscopy (SEM). These results show that cellulose/alginate hydrogels could provide many possible applications in the biomedical, and purification of the wastewater by adsorbing pollutants.
2018
Preparation of Activated Carbon from Helhelok Stones by Chemical Activation
2018-09
Journal of University of Zakho (Issue : 3) (Volume : 6)
In his study activated carbon was prepared from Helhelok stones as a raw material by using chemical activation with zinc chloride (ZnCl2) as a chemical agent with the concentration 40% for 25h at (25⁰C±2). The optimum conditions were approved in having carbonization temperature 400ᵒC for 1h to get a maximum percentage of yield 56%. Other properties of the prepared activated carbon were also studied such as pH, ash content, density, moisture content, conductivity, iodine number and methylene blue dye absorbance. Eventually the prepared activated carbon in this work has obtained good characteristics that make it play an essential role in industrial uses and compared it with commercial standard sample from B. D. H Company.
Studies on Preparation, Characterization and Biodegradation Behavior of HDPE Natural Polymers Blends
2018-03
Australian Jour nal of Basic and Applied Sciences (Issue : 3) (Volume : 14)
Polyethylene (HDPE) is widely used in various applications due to its chemical, physical. and biological inertness but its durability presents a great challenge when it is released in the environment. To reduce its adverse effect on environment, currently various efforts are being made to modify its properties using naturally occurring biodegradable polymers but still these modifications found to be costly and required biodegradability in polyethylene is not yet achieved. Therefore, an attempt has been made to deveop biodegradable polyethylene blends using naturally occurring polymers. In this connection biodegradable high density polyethylene (HDPE) blends were prepared by thermally blending 2.0, 5.0 and 10.0 wt % amount of naturally occurring polymers such as; chitosan (CH), cellulose(CE), starch (ST), alginate (AL), pectin (PE), shellac (SH) and xanthan (XA). The observed biodegradabilility in HDPE blends might be due to the presence of hydrolysable linkages and stereo-favourable orientations of blended natural polymers. The added polymers have played a significant role in increasing the hydrophilicity in blended HDPE and acted as a bioassimilative nutrients for seeded microorganisms. The biodegradability of HDPE-polymer blends was evaluated in presence of various fungi such as; aspergillus niger, aspergillus terreus, fusarium solani, tricoderma hariziauum and tricoderrma viride. The disinfected films of pristine HDPE and polymer blened HDPE were inoculated with these fungi and the extend of biodegrdation was evaluated after a incubation period of three months at 28 ± 1˚C. The biodegradability of HDPE-polymer blends was compared with pristine HDPE by evaluating their molecular weights, and weight percent loss in samples incubated for three months along with selected fungus. The biodegrdation in pristine HDPE and its polymer blends was confirmed by comparing their FT-IR spectra and also by evaluating the variations in their mechanical and thermal properties. A significant variation in their morphologies in prsence of fungi has confirmed biodegradation in HDPE-polymer blends in comparison to pristine HDPE films. These studies have provided sufficient evidnces to confirm the role of added natural polymers in developing a biodegradable HDPE by blending various polymers such as chitosan (CH), cellulose(CE), starch (ST), alginate (AL), pectin (PE), shellac (SH) and xanthan (XA). Out of these polymers, the chitosan is found to be quite effective as it is acted better bioassimilative nutrient for microorganisms to cause biodegrdation of HPEF in comparison to other polymers.
2017
Modeling and Optimization of Swelling, Drug loading and release from natural polymer hydrogels
2017-10
IOP Conference Series Materials Science and Engineering , at Istanbul, Turkey (Issue : 1) (Volume : 454)
The current work deals with synthesis of natural polymer hydrogels (Sodium alginate-Chitosan- Arabic Gum) as beads. The beads are formulated with different polymer proportions depending on the experimental central composite (design) Response Surface Methodology (RSM) has been used. The degree of swelling in acidic and neutral mediums was investigated, analyzed, modeled and optimized statistically. A typical drug (Allopurinol) was loaded by using optimized polymer formulations. The loading capacity and the in vitro release profiles were estimated. The shape and morphological analysis for the beads before and after drug releasing have been investigated also by using Scanning Electron Microscope. The results obtained confirmed that Arabic Gum content was a significant parameter in the swelling processes regardless the pH of the swelling media. Thus, swelling indices of the beads were higher in acidic medium (pH 3.9) compared to that once in (pH 7.1), to indicate a pH-sensitive swelling behavior. An optimum RSM results for swelling indices of 504.98 % and 207.97 % were obtained in acidic and neutral medium respectively. The in vitro drug release showed equilibrium after 12 hours where as (66.1- 85.7 %) and (44-54 %) was released at pH 3.9 and 7.1 respectively. The SEM analysis of the polymer beads confirmed that the beads had lost their shape due to erosion and swelling activities after releasing of the drug.
2016
Synthesis and Characterization of PVA-Gelatin Hydrogel Membranes for Controlled Delivery of Captopril
2016-09
International Research Journal of Pure & Applied Chemistry (Issue : 4) (Volume : 12)
Many biomedical applications including controlled drug delivery systems have been developed
based on hydrogel technologies. Different composite hydrogels including synthetic and natural
polymers can be produced to controllable systems in drug deliver application.
In this study, poly vinyl alcohol (PVA)-Gelatin hydrogel membranes were prepared by the
esterification reaction between hydroxyl groups of PVA and carboxyl groups of Gelatin to deliver
Captopril as a model of drug. Captopril was successfully loaded into PVA-Gelatin hydrogel
membrane in different ration of Gelatin (10:1, 10:2, 10:3, 10:4, 10:5, 10:6, 10:7, and 10:8). The
prepared hydrogel membranes were characterized by Fourier Transforms Infrared Spectroscopy
(FT-IR) and Scanning Electron Microscopy (SEM). The effects of different process parameters, like
percentage of Gelatin, size distribution, swelling behavior and in vitro drug releasing from hydrogel
membrane in different phosphate buffer solutions pH (7.1 and 3.9) were studied. The models of
kinetics of releasing drug were investigated by using different types of mechanisms (Zero-order,
First order, Higuchi’s model and Korsmeyer-Peppas Model).
Preparation and Characterization of PVA-NaAlg Interpenetrating Polymer Network (IPN) Hydrogel for Controlled Delivery of Carbidopa
2016-09
American Chemical Science Journal (Issue : 1) (Volume : 17)
Polymeric drug delivery systems are new developed technology. They can be used to support
patient’s compliance. They can help to maintain uniform drug levels and increase the safety margin
for high-potency drugs. Then, they decrease the number of daily doses.
Thus, in this study, Poly vinyl alcohol (PVA)-Sodium alginate (NaAlg) interpenetrating polymer
network (IPN) hydrogels were prepared by using Glutaraldehyde as a crosslinked. The model drug
(Carbidopa) was delivered by using emulsification / solvent-evaporation method. Carbidopa was
successfully loaded into PVA-NaAlg IPN hydrogels. The prepared IPN hydrogels were
characterized by Fourier Transforms Infrared Spectroscopy using (FT-IR) and Scanning Electron
Microscopy (SEM). The effects of different process parameters, like degree of swelling and In vitro
drug releasing of IPN hydrogel in different phosphate buffer solutions pH (7.1 and 3.9) were
studied. The models of kinetics of releasing drug were investigated by using different types of
mechanisms (Zero-order, First order, Higuchi’s model and Hixson-Crowell model).
Sodium Alginate - Gelatin Cross-Linked Microspheres for Releasing Diltiazem Hcl
2016-09
Journal of University of Zakho (Issue : 2) (Volume : 4)
Semi-interpenetrating polymer network (semi-IPN) microspheres of Sodium alginate (NaAlg) and
Gelatin were prepared and cross-linked with glutaraldehyde by using emulsification/solvent-evaporation
method to deliver Diltiazem HCl as a model of drug. Diltiazem HCl was successfully loaded into NaAlg-
Gelatin microspheres in different ratios of NaAlg and Gelatin. The prepared microspheres were
characterized by Fourier Transmission Infrared Microscopy (FT-IR) and Scanning Electron Microscope
(SEM). The effects of different process parameters, like percentage of polymers, swelling behavior and in
vitro drug release of microspheres in different phosphate buffer solutions pH (7.1and3.9) were studied.
The models of kinetics of releasing drug were investigated by using different types of mechanisms (Zeroorder,
First order, Higuchi’s model and Hixson-Crowell model).
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