S. Pradeep

A monograph on the remediation of hazardous phthalates

Phthalates or phthalic acid esters are a group of xenobiotic and hazardous compounds blended in plastics to enhance their plasticity and versatility. Enormous quantities of phthalates are produced globally for the production of plastic goods, whose disposal and leaching out into the surroundings cause serious concerns to the environment, biota and human health. Though in silico computational, in vitro mechanistic, pre-clinical animal and clinical human studies showed endocrine disruption, hepatotoxic, teratogenic and carcinogenic properties, usage of phthalates continues due to their cuteness, attractive chemical properties, low production cost and lack of suitable alternatives. Studies revealed that microbes isolated from phthalate-contaminated environmental niches efficiently bioremediate various phthalates. Based upon this background, this review addresses the enumeration of major phthalates used in industry, routes of environmental contamination, evidences for health hazards, routes for in situ and ex situ microbial degradation, bacterial pathways involved in the degradation, major enzymes involved in the degradation process, half-lives of phthalates in environments, etc. Briefly, this handy module would enable the readers, environmentalists and policy makers to understand the impact of phthalates on the environment and the biota, coupled with the concerted microbial efforts to alleviate the burden of ever increasing load posed by phthalates.

Mycelial fungi completely remediate di(2-ethylhexyl)phthalate, the hazardous plasticizer in PVC blood storage bag

This pioneering work describes how simply, inexpensively and efficiently novel fungi utilize the alarming plasticizer, di(2-ethylhexyl)phthalate (DEHP) blended in PVC blood storage bags (BB). In order to quantify total DEHP (33.5%, w/w) present in BB, it was extracted using n-hexane and confirmed by GC-MS. Three mycelial fungi, viz., Aspergillus parasiticus, Fusarium subglutinans and Penicillium funiculosum isolated in our laboratory form heavily plastics-contaminated soil - either singly or in consortium - completely consumed intact DEHP physically bound to BB by static submerged growth (28 °C) in simple basal salt medium (BSM). A two-stage cultivation strategy was adopted for the complete removal of DEHP from BB in situ. During the first growth stage, almost 70% DEHP contained in the BB was consumed in 2 weeks, accompanied by increased fungal biomass (~0.15-0.35 g/g BB; OD ~7 at 600 nm) and a sharp declining (3.3) of initial pH (7.2). Spent BSM was replaced at this stagnant growth state (low pH), thus in the second stage, remaining DEHP bound to BB utilized completely (over 99%). Furthermore, A. parasiticus and F. subglutinans also grew well on scrapes of PVC water pipes in BSM. F. subglutinans was as efficient independently as consortium in completely utilizing the DEHP bound to BB, and these fungi offer great potentials for the inexpensive and eco-friendly bioremediation of phthalates in medical and allied PVC wastes on a large scale through a batch process in alleviating the plactics waste management issue.

Phthalates efficiently bind to human peroxisome proliferator activated receptor and retinoid X receptor α, β, γ subtypes: an in silico approach.

This exhaustive in silico study looks into the molecular interactions of phthalates and their metabolites with human peroxisome proliferator‐activated receptor (hPPAR) and retinoid X receptor (hRXR) α, β and γ subtypes – the nuclear receptor proteins function as transcription factors by regulating the expression of downstream genes. Apart from the much discussed plasticizer bisphenol A, we examined the binding affinities of 15 common diphthalates and their monophthalates, natural (linoleic acid, conjugated linoleic acid) and synthetic (bezafibrate, pioglitazone, GW 50156) ligands with hPPARs. In addition to these phthalates, specific natural (retinoic and phytanic acids) and synthetic (bexarotene, rosiglitazone) ligands were examined with hRXRs. The Maestro, Schrödinger Suite 2012 was used for the molecular docking study. In general, natural ligands of hPPAR showed less binding efficiencies than phthalic acid esters and drugs. The diphthalate di‐iso‐decyl phthalate showed the highest G score (–9.99) with hPPAR (γ), while its monophthalate (mono‐iso‐decyl phthalate) showed a comparatively less G score (–9.56). Though the PPAR modulator GW 50156 showed strong affinity with all hPPAR subtypes, its highest G score (–12.43) was with hPPARβ. Hazardous di(2‐ethylhexyl)phthalate generally showed a greater preference to hRXRs than hPPARs, but its highest G score (–10.87) was with hRXRα; while its monophthalate (Mono(2‐ethylhexyl)phthalate) showed a lesser G score (–8.59). The drug bexarotene showed the highest G score (–13.32) with hRXRβ. Moreover, bisphenol A showed more affinity towards hRXR. Briefly, this study gives an overview on the preference of phthalic acid esters, natural and synthetic ligands on to hPPAR and hRXR subtypes, which would lead to further in vitro mechanistic as well as in vivo preclinical and clinical studies. Copyright

Achromobacter denitrificans strain SP1 efficiently remediates di(2-ethylhexyl)phthalate.

This study describes how Achromobacter denitrificans strain SP1, a novel isolate from heavily plastics-contaminated sewage sludge efficiently consumed the hazardous plasticizer, di(2-ethylhexyl)phthalate (DEHP) as carbon source supplemented in a simple basal salt medium (BSM). Response surface methodology was employed for the statistical optimization of the process parameters such as temperature (32°C), agitation (200 rpm), DEHP concentration (10 mM), time (72 h) and pH (8.0). At these optimized conditions, experimentally observed DEHP degradation was 63%, while the predicted value was 59.2%; and the correlation coefficient between them was 0.998, i.e., highly significant and fit to the predicted model. Employing GC-MS analysis, the degradation pathway was partially deduced with intermediates such as mono(2-ethylhexyl)phthalate and 2-ethyl hexanol. Briefly, this first report describes A. denitrificans strain SP1 as a highly efficient bacterium for completely remediating the hazardous DEHP (10 mM) in 96 h in BSM (50% consumed in 60 h), which offers great potentials for efficiently cleaning the DEHP-contaminated environments such as soil, sediments and water upon its deployment.

Human ketosteroid receptors interact with hazardous phthalate plasticizers and their metabolites: an in silico study.

Phthalic acid esters or phthalates are ubiquitous environmental pollutants known for their adverse health effects in test animals and, of late, in humans. Thus, in this molecular docking study – using Glide (Schrödinger) – the molecular interactions of 31 ligands, including 12 diphthalates, their monophthalates and phthalic acid with selected human ketosteroid receptors, i.e., androgen (hAR), progesterone (hPR) and glucocorticoid (hGR) receptors were explored and their binding affinities were compared with that of corresponding natural steroids and a known endocrine disrupting xenobiotic, bisphenol A (BPA). Mostly, diphthalates and monophthalates showed the potential for antisteroidal activity by interacting with hAR, hPR and hGR. Of them, diphenyl phthalate showed the highest G score (–7.70 kcal mol–1) with hAR, and the crucial amino acid (aa) residues in the ligand binding domain (LBD) of this receptor involved in the molecular interactions were Phe 764, Leu 704, Asn 705 and Thr 877. The mono‐iso‐decyl phthalate showed the highest G score (–8.36) with the hPR, and the crucial aa residues in the LBD interactions were Arg 766 Gln 725 and Phe 778. The mono‐iso‐decyl phthalate also showed more affinity (–8.44) towards hGR than the natural ligand, and the aa residues in the LBD interactions were Gln 570 and Met 604. In addition to these, some other phthalates established comparable interactions with certain aa residues located in the LBD of these receptors, which resulted in higher G scores. Contrastingly, BPA and some natural ligands tested in this study showed lower G scores with these receptors than certain phthalates reported herein, i.e., certain phthalates are more toxic than the proven toxic BPA. Copyright

In silico evidences for the binding of phthalates onto human estrogen receptor α, β subtypes and human estrogen-related receptor γ

Being lipophilic xenobiotic chemicals, phthalates from the surrounding environments can easily be absorbed into the biological system, thereby causing various health problems including cancer and endocrine disruption in test animals and also in humans. In the present in silico study employing Glide, Schrödinger Suite 2012, we analysed in detail the binding affinities of 12 commonly used diphthalates and their metabolites (corresponding mono ester and phthalic acid) onto the ligand-binding domain (LBD) of the human estrogen receptor α (hERα), human estrogen receptor β (hERβ) and human estrogen related receptor γ (hERRγ). Natural ligand 17β estradiol (E2), known xenoestrogen bisphenol A, the phytoestrogen genistein, the agonists/antagonists 4-hydroxy tamoxifen and raloxifene were also docked onto these receptors as positive controls for comparing the binding efficiencies with that of phthalates and their metabolites. Results revealed that E2 had less binding affinity to the receptors in comparison to certain phthalates, i.e. maximum binding scores (G score, kcal/mol) were diisononyl phthalate ( − 9.44) to hERα, monophenyl phthalate ( − 8.66) to hERβ and di(2-ethylhexyl)phthalate ( − 9.38) to hERRγ. The most concerned monophthalates established additional H bonds with certain surrounding crucial amino acid residues in the LBD, and thus showed more affinity to all the receptors than even the natural ligand and other well-characterised xenoestrogens as demonstrated in this study. Briefly, this study gives an insight into the virtual binding behaviours of commonly used phthalates and their metabolites onto hERs and hERRγ, which would accelerate further in vitro mechanistic, preclinical and clinical studies on real in vitro or in vivo platforms.

Achromobacter denitrificans SP1 produces pharmaceutically active 25C prodigiosin upon utilizing hazardous di(2-ethylhexyl)phthalate.

This first report describes the purification and identification of an orange-red pigment produced by Achromobacter denitrificans strain SP1 (isolated from sewage sludge heavily contaminated with plastics) during its growth in a simple basal salt medium supplemented with the hazardous di(2-ethylhexyl)phthalate (DEHP) blended in PVC blood bag (in situ) or free DEHP (ex situ) as carbon source. The cell-bound pigment was elucidated, characterized at molecular level, and described as an unusual 25C prodigiosin analog for the first time. At laboratory conditions (in flasks), the dry cell mass was 75.2mg/g blood bag, which upon extraction yielded 7.1mg prodigiosin; at this stage the pH of the medium was dropped from 7.2 to 3.5. Considering its pharmaceutical importance, taking 10 known prodigiosins as controls, this 25C prodigiosin was subjected to molecular docking studies, showed comparable and promising binding efficiencies with the crucial molecular human targets like cycloxygenase-2, ZAP-70 kinase and Jak-3 kinase.

Accessing the molecular interactions of phthalates and their primary metabolites with the human pregnane X receptor using in silico profiling.

Phthalates are known to cause endocrine disruption in humans and animals. Being lipophilic xenobiotic chemicals, phthalates from the surrounding environments can easily be absorbed into the biological system, thereby causing various health dysfunctions. This molecular docking study evaluates a variety of molecular interactions of 12 commonly used diphthalates and respective monophthalates onto the ligand binding domain (LBD) of the human pregnane X receptor (hPXR), a xenosensor, which would be beneficial for further in vitro and in vivo studies on hazardous phthalates. Out of 12 diphthalates and their monophthalates tested, diisodecyl phthalate (–9.16 kcal mol–1) showed more affinity toward hPXR whereas diisononyl phthalate (–8.77) and di(2‐ethyhexyl)phthalate (–8.56), the predominant plasticizers found in a variety of plastics and allied products, showed comparable binding scores with that of the control ligands such as hyperforine (–9.99) and dexamethasone (–7.36). In addition to the above diphthalates, some of their monophthalates (monoisodecyl phthalate, mono‐2‐etheylhexyl phthalate, etc.) also established similar interactions with certain crucial amino acids in the LBD, which led to higher G scores. In fact, bisphenol A, a well‐studied and proven endocrine disruptor, showed lesser G scores (–6.69) than certain phthalates. Copyright

Microbial bioprocess for the remediation of the hazardous di(2-ethylhexyl)phthalate

The interactions of compounds on human cell lines are either influenced by the composition of substances present in plant material or alteration of constituents by solvent fractionation. These substances or constituents have an influence on the percentage cytotoxicity readings of compounds in human cell culture. Understanding and correlating the relationship between cytotoxicity and other parameters, such as cell death inducing mechanisms, will assist pharmaceutical chemists to synthesize compounds that can target particular ailments with greater efficiency. This will also allow scientists to understand the interaction of compounds with different cell types for different compound fractions.A totally new comprehensive index is proposed, called Q, which can effectively discriminate artificial adulterated milk from unadulterated milk. Both normal and adulterated samples of bovine raw milk were analyzed by Fourier transform infrared spectroscopic instrument to measure the traditional indices of quality, including fat (FAT), protein (PRO), lactose (LAC), total solids (TS), non-fat solid (NFS), freezing point (FP) and somatic cell counts (SCC). From these traditional indices, a multivariate method is elaborated to build the comprehensive index Q. First, correlated analysis and principle component analysis were used to select parameter pairs TS-FAT and FP-LAC as predominant variables. Second, linear-regression analysis and residual analysis are applied to determine the index Q and its discriminating ranges. The verification and two-blind trial results suggested that index Qcould accurately detect milk adulteration with maltodextrin and water (as low as 1.0%of adulteration proportions), and withother nine kinds of synthetic adulterants (as low as 0.5% ofadulteration proportions).P implantitis which is one of etiologic factors associated with implant failure is mostly caused by bacteria, and can be prevented by inhibiting bacterial adhesion on implant surface. The aim of this study was to evaluate the response of Streptococcus mutans (S. mutans) and Porphyromonas gingivalis (P. gingivalis) via crystal violet staining assay on titanium surface modified by TiN sputter coating and plasma nitriding on titanium. The specimens were divided into 3 groups; polished titanium (control group), titanium modified by DC magnetron sputtering (group TiN-Ti), and titanium modified by plasma nitriding (group N-Ti). The surface characteristics of specimens were observed by using the nanosurface 3D optical profiler and field emission scanning electron microscope. Group TiN-Ti were showed TiN layer 1.2 μm in thickness and group N-Ti was identified as plasma nitriding with X-ray photoelectron spectroscopy. Roughness average (Ra) of all specimens values ≤0.2 μm, threshold Ra, which has no effect on bacterial adhesion. No significant differences of S. mutans adhesion between the surfaces of control, group TiN-Ti, and group N-Ti (P>0.05). In the result of the adhesion of P. gingivalis, there was no statistically significant difference between group TiN-Ti and control group, while group N-Ti had statistically significant higher absorbance level than the other groups (p<0.05). This indicates that too much thin modified surface could not influence the bacterial adhesion because of deficient of masking effect. Therefore TiN layer must be thick enough to make masking effect but also surface roughness values under “threshold Ra”, 0.2 μm.