J. Sivasubramanian

Characterizations of diverse mole of pure and Ni-doped α-Fe2O3 synthesized nanoparticles through chemical precipitation route

In the present study, an attempt has been made for characterization and synthesis of pure and Ni-doped α-Fe2O3 (hematite) nanoparticles by chemical precipitation method. The synthesized products have been studied by X-ray diffraction (X-RD), Fourier transform infrared (FTIR) spectroscopy, UV-Vis diffuse reflectance spectroscopy (UV-Vis DRS), vibrating sample magnetometer (VSM) and scanning electron microscopy (SEM) techniques. The estimated average diameter of α-Fe2O3 nanoparticles were calculated by using the Debye-Scherrer equation and established as 31 nm. SEM micrographs showed the surface morphology as well as structures and particles distributions of synthesized samples. The UV-Vis DRS showed the indirect and direct band gap energies of pure and Ni-doped α-Fe2O3, these were reduced from 1.9847 to 1.52 eV and 2.0503 to 1.76 eV respectively. This result suggested the dopant enhanced the semiconducting behavior of iron oxide nanoparticles to an extent proportional to its nickel doped in the α-Fe2O3. Further, the magnetic properties of the pure and doped samples were investigated by vibrating sample magnetometer (VSM) and evaluated the information of pure and doped samples exhibited saturated hysteresis loop at room temperature, which is indicating that the weak ferromagnetism in nature of our synthesized samples. In addition, it has been found from the magnetization hysteresis curves of Ni-doping, resulting from increased the saturation of magnetization and reduced the coercivity of used samples. Therefore, the present study showed the reduction in band gap energies and coercive field for α-Fe2O3 nanoparticles due to nickel doped.

Molecular metabolic fingerprinting approach to investigate the effects of borneol on metabolic alterations in the liver of nitric oxide deficient hypertensive rats

Hypertension is one of the major risk factor that underlie a wide range of cardiovascular irregularities which causes functional and metabolic alterations in vascular system and major organs. Nitric oxide is the central regulator of the vascular system and its deficiency leads to increased blood pressure and metabolic alterations in liver. Fourier transform infrared spectroscopy (FTIR) is a vibrational spectroscopic technique that uses infrared radiation to vibrate molecular bonds with in the sample that absorbs it and different samples contain diverse configurations of molecular bonds. Both wavenumber and area of the vibrational spectra can be used to explore the qualitative and quantitative constituent of macromolecules. In this study, we intended to evaluate the protective role of borneol, a natural terpene on liver metabolism in a nitric oxide deficient model of hypertension through interpretation of FTIR spectral information. Results demonstrate that FTIR can successfully indicate the molecular changes that occur in all groups. The over all findings demonstrate that in nitric oxide deficient animal model of hypertension, the liver metabolic program is altered through increasing the structural modification in proteins and triglycerides, and quantitative alteration in proteins, lipids, and glycogen. All the above mentioned modifications were protected by borneol in liver and showed its ability to exert a novel defensive action on hepatic metabolism.

Bioaccumulations of aluminum and the effects of chelating agents on different organs of Cirrhinus mrigala.

The study of biological indicator organisms may be more informative than analyzing water or sediments for monitoring heavy metal pollution in the aquatic environment. Non-essential elements enter into the animals and accumulate at the different organs so that chelating agents are most versatile and effective antidotes to eliminate the metals toxicities. The aim of our present study is to find out bioaccumulations of aluminum and the effects of chelating agents DFO and DFP in Muscle, gill, kidney, brain and liver tissues of Cirrhinus mrigala by using inductively coupled atomic emission spectrometry (ICP-AES). This study determined that the accumulation pattern of aluminum is muscle > gill > kidney > brain > liver. The present result suggests that DFO and DFP reduce the aluminum concentration in the tissues of C. mrigala fish and both are efficient chelators. Aluminum toxicity is a widespread problem in all forms of life, including humans, animals, fish, plants, and causes wide spread degradation of the environment and health.

Studies the alterations of biochemical and mineral contents in bone tissue of mus musculus due to aluminum toxicity and the protective action of desferrioxamine and deferiprone by FTIR, ICP-OES, SEM and XRD techniques.

The present study has attempt to analyze the changes in the biochemical and mineral contents of aluminum intoxicated bone and determine the protective action of desferrioxamine (DFO) and deferiprone (DFP) by using Fourier transform infrared (FTIR) spectroscopy, X-ray diffraction (XRD), inductively coupled plasma optical emission spectroscopy (ICP-OES), and scanning electron microscopy (SEM) techniques for four groups of animals such as control (Group I), aluminum intoxicated (Group II), Al+DFP (Group III) and Al+DFO+DFP (Group IV) treated groups respectively. The FTIR spectra of the aluminum intoxicated bone showed significant alteration in the biochemical constituents. The bands ratio at I1400/I877 significantly decreased from control to aluminum, but enhanced it by Al+DFP to Al+DFO+DFP treated bone tissue for treatments of 16 weeks. This result suggests that DFO and DFP are the carbonate inhibitor, recovered from chronic growth of bone diseases and pathologies. The alteration of proteins profile indicated by Amide I and Amide II, where peak area values decreased from control to aluminum respectively, but enhanced by treated with DFP (p.o.) and DFO+DFP (i.p.) respectively. The XRD analysis showed a decrease in crystallinity due to aluminum toxicity. Further, the Ca, Mg, and P contents of the aluminum exposed bone were less than those of the control group, and enhanced by treatments with DFO and DFP. The concentrations of trace elements were found by ICP-OES. Therefore, present study suggests that due to aluminum toxicity severe loss of bone minerals, decrease in the biochemical constituents and changes in the surface morphology.

Aluminium induced structural, metabolic alterations and protective effects of desferrioxamine in the brain tissue of mice: an FTIR study.

In this study, we intended to made a new approach to evaluate aluminium induced metabolic changes in mice brain tissue using Fourier transform infrared spectroscopy. Results demonstrate that FTIR can successfully indicate the molecular changes that occur in all groups. The overall findings demonstrate the alterations on the major biochemical constituents, such as lipids, proteins and nucleic acids of the brain tissues of mice. The significant decrease in the area value of amide A peak and Olefinic = CH stretching band suggests an alteration in the protein profile and lipid levels due to aluminium exposure, respectively. The significant shift in the amide I and amide II protein peaks may indicate the progression of aluminium induced Alzheimers disease. Further the administration of DFO significantly improved the level of protein and brought back the amide I and II peaks nearer to the control value. Histopathological results also revealed impairment of Aluminium induced alterations in brain tissue. The results of the FTIR study were found to be in agreement with biochemical studies.

FTIR study of protective action of deferoxamine and deferiprone on the kidney tissues of aluminum loaded mice

The present study was designed to evaluate the FTIR spectra of the aluminum exposed kidney tissues and recovered by chelating agents DFO and DFP then showed significant alteration on the major biochemical constituents such as lipids, proteins and glycogen at molecular level. The significant increased in the peak area of glycogen from 0.006±0.001 to 0.187±0.032 may be the interruption of aluminum in the calcium metabolism and the reduced level of calcium. The peak area value of amide A significantly decreased from control (4.931±1.446) to aluminum (1.234±0.052), but improved by DFP and DFO+DFP from 2.658±0.153 to 3.252±0.070 respectively. Amide I and amide II peak area values also decreased from 1.690±0.133 to 0.811±0.192 and 1.158±0.050 to 0.489±0.047 but treated with DFP and DFO+DFP significantly improved. This result suggests an alteration in the protein profile. The absence of Olefinic=CH stretching band, C=O stretching of triglycerides and ring breathing mode in the DNA bases in aluminum exposure kidney suggests an altered lipid levels. Treated with DFP and DFO+DFP mice were considerably increased in lipid peroxidative markers. Further, assessed the activities of enzymatic antioxidants and measured the levels of nonenzymatic antioxidants. Concentrations of trace elements were found by ICP-OES. Histopathology of chelating agents treated kidney showed reduced renal damage in aluminum induced mice. Thus, histopathological findings confirmed the biochemical observations of this study. This results demonstrated that FTIR spectroscopy can be successfully applied to toxicological and biotoxicology studies.

Determination of aluminium induced metabolic changes in mice liver: a Fourier transform infrared spectroscopy study.

In this study, we made a new approach to evaluate aluminium induced metabolic changes in liver tissue of mice using Fourier transform infrared spectroscopy analysis taking one step further in correlation with strong biochemical evidence. This finding reveals the alterations on the major biochemical constituents, such as lipids, proteins, nucleic acids and glycogen of the liver tissues of mice. The peak area value of amide A significantly decrease from 288.278±3.121 to 189.872±2.012 between control and aluminium treated liver tissue respectively. Amide I and amide II peak area value also decrease from 40.749±2.052 to 21.170±1.311 and 13.167±1.441 to 8.953±0.548 in aluminium treated liver tissue respectively. This result suggests an alteration in the protein profile. The absence of olefinicCH stretching band and CO stretching of triglycerides in aluminium treated liver suggests an altered lipid levels due to aluminium exposure. Significant shift in the peak position of glycogen may be the interruption of aluminium in the calcium metabolism and the reduced level of calcium. The overall findings exhibit that the liver metabolic program is altered through increasing the structural modification in proteins, triglycerides and quantitative alteration in proteins, lipids, and glycogen. All the above mentioned modifications were protected in desferrioxamine treated mice. Histopathological results also revealed impairment of aluminium induced alterations in liver tissue. The results of the FTIR study were found to be in agreement with biochemical studies and which demonstrate FTIR can be used successfully to indicate the molecular level changes.

FT-Raman study of deferoxamine and deferiprone exhibits potent amelioration of structural changes in the liver tissues of mice due to aluminum exposure.

The present study inform the alterations on major biochemical constituents such as lipids, proteins, nucleic acids and glycogen along with phosphodiester linkages, tryptophan bands, tyrosine doublet, disulfide bridge conformations, aliphatic hydrophobic residue, and salt bridges in liver tissues of mice using Fourier transform Raman spectroscopy. In amide I, amide II and amide III, the area value significant decrease due structural alteration in the protein, glycogen and triglycerides levels but chelating agents DFP and DFO upturned it. Morphology changes by aluminium induced alterations and recovery by chelating agents within liver tissues known by histopathological examination. Concentrations of trace elements were found by ICP-OES. FT-Raman study was revealed to be in agreement with biochemical studies and demonstrate that it can successfully specify the molecular alteration in liver tissues. The tyrosyl doublet ratio I899/I831 decreases more in aluminum intoxicated tissues but treatment with DFP and DFO+DFP brings back to nearer control value. This indicates more variation in the hydrogen bonding of the phenolic hydroxyl group due to aluminum poisoning. The decreased Raman intensity ratio (I3220/I3400) observed in the aluminum induced tissues suggests a decreased water domain size, which could be interpreted in terms of weaker hydrogen-bonded molecular species of water in the aluminum intoxicated liver tissues. Finally, FT-Raman spectroscopy might be a useful tool for obtained successfully to indicate the molecular level changes.

Aluminium induced metabolic changes in kidney and heart tissue of mice: a Fourier transform infrared spectroscopy study

In this study, we aimed to evaluate aluminium induced metabolic changes in kidney and heart tissues of mice using Fourier transform infrared spectroscopy analysis. This result revealed the alterations on the major biochemical constituents, such as lipids, proteins and nucleic acids of the kidney tissues of mice. In aluminium intoxicated kidney tissue significant shift and decrease in the area value of the amide A band and decrease in protein-to-lipid ratio indicated quantitative and qualitative alterations in the protein profile due to iron-initiated free radical formation. Shift in the peak position of the PO2− asymmetric stretching band for aluminium intoxicated kidney tissue indicated the dehydrated phosphate group. This might be due to the binding of aluminium with phosphate or interruption of aluminium in calcium metabolism. The increased level of serum uric acid might have resulted from the essential hypertension, which might be due to marked accumulation of O2˙ in the kidney. All of the above mentioned modifications were protected in Desferrioxamine treated mice. The overall findings exhibited that aluminium toxicity might induce essential hypertension through the dysfunction of kidneys. The results of the FTIR study were found to be in agreement with biochemical studies which demonstrated that FTIR could be used successfully to indicate the molecular level changes.

Diosgenin prevents hepatic oxidative stress, lipid peroxidation and molecular alterations in chronic renal failure rats

Aim: Chronic renal failure (CRF) is one of the major contributors of cardiovascular pathological events and CRF associated uremic condition in rats elevates liver oxidative stress. The aim of the present study was to evaluate the preventive potential of diosgenin on antioxidant system and molecular protection potential in liver of CRF rats. Materials and Methods: CRF in rats was induced by feeding rats with diet containing 0.75% adenine for 5 weeks. Diosgenin was given orally at a dose of 40 mg/kg body weight (bw) of animal each and every day. The activities of antioxidant enzymes and lipid peroxidation level were determined by biochemical assays. Fourier transform infrared spectroscopy (FTIR) was employed to illustrate the molecular protection potential of diosgenin. Results: This study has shown adenine containing diet induced CRF in rats elevates liver oxidative stress by suppressing the activity of enzymatic antioxidant system, increased lipid peroxidation, and macromolecular structural alterations. In this study, treatment of diosgenin 40 mg/kg bw of rat significantly restores the enzymatic antioxidant system and reduces the lipid peroxidation level. Moreover, based on the FTIR study, we confirmed that diosgenin administration significantly protected the macromolecular changes including, the protein structural damage that occurred in liver. Conclusion: This study has proved the hepato protective action of diosgenin through antioxidant and molecular protection effect in CRF condition.