Agronomic Investigation of Spray Dispersion of Metal-Based Nanoparticles on Sunflowers in Real-World Environments.

In environmental and agronomic settings, even minor imbalances can trigger a range of unpredicted responses. Despite the widespread use of metal-based nanoparticles (NPs) and new bio-nanofertilizers, their impact on crop production is absent in the literature. Therefore, our research is focused on the agronomic effect of spray application of gold nanoparticles anchored to SiO2 mesoporous silica (AuSi-NPs), zinc oxide nanoparticles (ZnO-NPs), and iron oxide nanoparticles (Fe3O4-NPs) on sunflowers under real-world environments. Our findings revealed that the biosynthetically prepared AuSi-NPs and ZnO-NPs were highly effective in enhancing sunflower seasonal physiology, e.g., the value of the NDVI index increased from 0.012 to 0.025 after AuSi-NPs application. The distribution of leaf trichomes improved and the grain yield increased from 2.47 t ha-1 to 3.29 t ha-1 after ZnO-NPs application. AuSi-NPs treatment resulted in a higher content of essential linoleic acid (54.37%) when compared to the NPs-free control (51.57%), which had a higher determined oleic acid. No NPs or residual translocated metals were detected in the fully ripe sunflower seeds, except for slightly higher silica content after the AuSi-NPs treatment. Additionally, AuSi-NPs and NPs-free control showed wide insect biodiversity while ZnO-NPs treatment had the lowest value of phosphorus as anti-nutrient. Contradictory but insignificant effect on physiology, yield, and insect biodiversity was observed in Fe3O4-NPs treatment. Therefore, further studies are needed to fully understand the long-term environmental and agricultural sustainability of NPs applications.

Molecular Weight Controls Interactions between Plastic Deformation and Fracture in Cold Spray of Glassy Polymers.

Polymer cold spray has gained considerable attention as a novel manufacturing process. A promising aspect of this technology involves the ability to deposit uniform polymer coatings without the requirements of solvent and/or high-temperature conditions. The present study investigates the interplay between shear instability, often considered to be the primary mechanism for bond formation, and fracture, as a secondary energy dissipation mechanism, collectively governing the deposition of glassy thermoplastics on similar and dissimilar substrates. A hybrid experimental-computational approach is utilized to explore the simultaneous effects of several interconnected phenomena, namely the particle-substrate relative deformability, molecular weights, and the resultant yielding versus fracture of polystyrene particles, examined herein as a model material system. The computational investigations are based on constitutive plasticity and damage equations determined and calibrated based on a statistical data mining approach applied to a wide collection of previously reported stress-strain and failure data. Results obtained herein demonstrate that the underlying adhesion mechanisms depend strongly on the molecular weight of the sprayed particles. It is also shown that although the plastic deformation and shear instability are still the primary bond formation mechanisms, the molecular-weight-dependent fracture of the sprayed glassy polymers is also a considerable phenomenon capable of significantly affecting the deposition process, especially in cases involving the cold spray of soft thermoplastics on hard substrates. The strong interplay between molecular-weight-dependent plastic yielding and fracture in the examined system emphasizes the importance of molecular weight as a critical variable in the cold spray of glassy polymers, also highlighting the possibility of process optimization by proper feedstock selection.

Improving biofortification success rates and productivity through zinc nanocomposites in rice (Oryza sativa L.).

Rice (Oryza sativa L.) is a staple food crop; most of it is consumed in nations where malnutrition is a serious problem, and its enrichment through biofortification can be used to efficiently combat hidden hunger. Here, we studied the effect of two zinc forms, i.e., zinc oxide nanoparticles (ZnO NPs) and sulfate salt (ZnSO4), at four different concentrations during the grain development period (after anthesis and continued once a week for up to 5 weeks) of the rice plant. During the rice growing season 2021-2022, all the experiments were conducted in a greenhouse (temperature: day 30 °C; night 20 °C; relative humidity: 70%; light period: 16 h/8 h, day/night). The main aim was to identify the effects of ZnO NPs on physical growth, biochemical parameters, nutrient acquisition, and crop yield. We have also highlighted the effects of NPs on zinc biofortification, and the end results illustrated that both zinc forms are capable of increasing grain yield. However, we found that even at low concentrations, ZnO NPs showed a significant increase in growth yield, whereas bulk did not show eminent results even at higher concentrations. Spikelet number per panicle was more than 50% and 38% in the case of ZnO NPs and ZnSO4, respectively. Similarly, stimulation in plant height was 25% with NPs treatment and only 3% with bulk treatment. The increase in grain per spike was 19% with ZnO NPs as compared to the control. Total chlorophyll, soluble sugar, amylose, and soluble protein contents were enhanced under ZnO NP treatment, which plays an excellent role in the regulation of various transcriptional pathways related to biofortification. We identified that foliar application at the flowering stage is more effective in comparison to the basal and tillering stages of the rice life cycle. ZnO NPs increased zinc content in rice grain by 55% as compared to traditional fertilization (~ 35%), with no adverse effects on human health. This study highlights that ZnO NPs could be used to increase zinc efficiency and as a safe fertilizer in the rice harvesting ecosystem.

Effect of zinc and iron oxide nanoparticles on plant physiology, seed quality and microbial community structure in a rice-soil-microbial ecosystem.

In this study, we assessed the impact of zinc oxide (ZnO) and iron oxide (FeO) (<36 nm) nanoparticles (NPs) as well as their sulphate salt (bulk) counterpart (0, 25, 100 mg/kg) on rice growth and seed quality as well as the microbial community in the rhizosphere environment of rice. During the rice growing season 2021-22, all experiments were conducted in a greenhouse (temperature: day 30 °C; night 20 °C; relative humidity: 70%; light period: 16 h/8 h, day/night) in rice field soil. Results showed that low concentrations of FeO and ZnO NPs (25 mg/kg) promoted rice growth (height (29%, 16%), pigment content (2%, 3%)) and grain quality parameters such as grains per spike (8%, 9%), dry weight of grains (12%, 14%) respectively. As compared to the control group, the Zn (2%) and Fe (5%) accumulations at their respective low concentrations of NP treatments showed stimulation. Interestingly, our results showed that at low concentration of both the NPs the soil microbes had more diversity and richness than those in the bulk treated and control soil group. Although a number of phyla were affected by the presence of NPs, the strongest effects were observed for change in the abundance of the three phyla for Proteobacteria, Actinobacteria, and Planctomycetes. The rhizosphere environment was notably enriched with potential streptomycin producers, carbon and nitrogen fixers, and lignin degraders with regard to functional groups of microorganisms. However, microbial communities mainly responsible for chitin degradation, ammonia oxidation, and nitrite reduction were found to be decreased. The results from this study highlight significant changes in several plant-based endpoints, as well as the rhizosphere soil microorganisms. It further adds information to our understanding of the nanoscale-specific impacts of important micronutrient oxides on both rice and its associated soil microbiome.

Structural analysis of extrafloral nectaries of Senna occidentalis L.: insights on diversity and evolution.

MAIN CONCLUSION: The extrafloral nectaries of S. occidentalis were studied structurally and anatomically (at secretory and post-secretory developmental stages). Role of extrafloral nectaries as a common plant-adoptive characteristic in context to diversity and phylogenetic pattern was also speculated while exploring other collaborative evolutionary implications of this plant. Extrafloral nectaries (EFNs) are widespread and evolutionarily labile traits that have repeatedly and remarkably evolved in vascular plants. Morphological descriptions of the EFNs of certain plant species are common in the literature, but they rarely relate morphology with histology, gland distribution and secretory characteristics. Studies relating EFNs features, i.e., morphology and distribution with their differential visitation by insects, viz. ants and the cost of maintenance to the plants are important to understand the evolution of these glands. Therefore, in this study a morphological, anatomical (structure and ultrastructure) and secretory characterization of EFNs occurring on Senna occidentalis L. is made with the implications of gland attributes discussed from a functional perspective. S. occidentalis L. (Caesalpiniaceae) is an economically important species from industrial, medicinal and agricultural perspective. Observations from the result showed that shape of the EFNs (size 1-2 mm) ranged to globular, ovoid-conical, dome-shaped, fusiform or cylindrical with conical tip. The EFNs were sessile, positioned interpetiolar or seated at the base of petiole. Light and transmission electron microscopic studies showed the specific internal structures of the extrafloral nectary. Two developmental stages of the EFNs (secretory and post-secretory) were recognized. Our current understanding of the phylogenetic patterns of EFNs makes them powerful candidates for future work exploring the drivers of their evolutionary origins, shifts, and losses.

Transcriptomic landscape of early age onset of colorectal cancer identifies novel genes and pathways in Indian CRC patients.

Past decades of the current millennium have witnessed an unprecedented rise in Early age Onset of Colo Rectal Cancer (EOCRC) cases in India as well as across the globe. Unfortunately, EOCRCs are diagnosed at a more advanced stage of cancer. Moreover, the aetiology of EOCRC is not fully explored and still remains obscure. This study is aimed towards the identification of genes and pathways implicated in the EOCRC. In the present study, we performed high throughput RNA sequencing of colorectal tumor tissues for four EOCRC (median age 43.5 years) samples with adjacent mucosa and performed subsequent bioinformatics analysis to identify novel deregulated pathways and genes. Our integrated analysis identifies 17 hub genes (INSR, TNS1, IL1RAP, CD22, FCRLA, CXCL3, HGF, MS4A1, CD79B, CXCR2, IL1A, PTPN11, IRS1, IL1B, MET, TCL1A, and IL1R1). Pathway analysis of identified genes revealed that they were involved in the MAPK signaling pathway, hematopoietic cell lineage, cytokine-cytokine receptor pathway and PI3K-Akt signaling pathway. Survival and stage plot analysis identified four genes CXCL3, IL1B, MET and TNS1 genes (p = 0.015, 0.038, 0.049 and 0.011 respectively), significantly associated with overall survival. Further, differential expression of TNS1 and MET were confirmed on the validation cohort of the 5 EOCRCs (median age < 50 years and sporadic origin). This is the first approach to find early age onset biomarkers in Indian CRC patients. Among these TNS1 and MET are novel for EOCRC and may serve as potential biomarkers and novel therapeutic targets in future.

Nanopriming with phytosynthesized zinc oxide nanoparticles for promoting germination and starch metabolism in rice seeds.

The application of zinc oxide nanoparticles (ZnO NPs) in agricultural field is emerging and relatively new. In this work, a simple, cost-efficient, non-toxic and eco-friendly method for the green synthesis of ZnO NPs by Senna occidentalis leaf extract has been described. Techniques used to characterize nanoparticles (NPs) were X-ray diffractometer (XRD), UV visible spectroscopy, Particle size analyzer (PSA), Fourier transform infrared spectroscopy (FTIR) and Scanning electron microscopy (SEM). In this study, green synthesized ZnO NPs at 20-40 mg/l solution was used to prime aged seeds of early flowering homozygous mutant (BM6) of Pusa basmati (Oryza sativa), which enhanced germination performance and seedling vigor significantly as compared to zinc sulphate (ZnSO4) priming and conventional hydropriming. The effect of treatment was analyzed by measuring biophysical and biochemical parameter of germinating rice seeds. The seeds treated with ZnO NPs of 20 mg/l concentration showed more than 50 % stimulation in dry weight, relative water uptake of seeds and radicle length of seedling in comparison to other priming solution and control (hydro-primed). Significant growth was also observed in plumule length and fresh weight of seeds in ZnO NPs at 20 mg/l concentration in comparison to control and other priming treatments. At the same concentration of ZnO NPs, there was 23 % stimulation reported in total soluble sugar content and 45 % stimulation in amylase activity. There was also a substantial increase in antioxidant enzymes i.e. superoxide dismutase (SOD), catalase (CAT) and ascorbate peroxidase (APX) activity. Seed priming represents an innovative user-friendly approach to enhance the germination rate, starch metabolic process and triggered zinc acquisition of rice aged seed as an alternative to the conventional priming method.

Molecular subtypes of colorectal cancer: An emerging therapeutic opportunity for personalized medicine.

Molecular subtypes-based therapies offer new potential framework for desired and precise outcome in clinical settings. Current treatment strategies in colorectal cancer are largely 'one drug fit all' model for patients that display same pathological conditions. However, CRC is a very heterogenous set of malignancy that does not support for above criteria. Each subtype displays different pathological and genetic signatures. Based on these features, therapeutic stratification for individual patients may be designed, which may ultimately lead to improved therapeutic outcomes. In this comprehensive review, we have attempted to briefly outline major CRC pathways. A detailed overview of molecular subtypes and their clinical significance has been discussed. Present and future methods, governing CRC subtyping in the era of personalized therapy with a special emphasis on CMS subtypes of CRC has been reviewed. Together, discovery and validation of new CRC patient stratification methods, screening for novel therapeutic targets, and enhanced diagnosis of CRC may improve the treatment outcome.

Eco-friendly synthesis of phytochemical-capped iron oxide nanoparticles as nano-priming agent for boosting seed germination in rice (Oryza sativa L.).

Recently the applications of engineered nanoparticles in the agricultural sector is increased as nano-pesticides, nano-fertilizers, nanocarrier for macro- or micronutrients, nano-sensors, etc. In this study, biocompatible iron oxide nanoparticles (FeO NPs) have been synthesized through an environment-friendly route using Cassia occidentalis L. flower extract to act as nano-priming agent for promoting germination of Pusa basmati rice seeds. Different characterization methods, viz. X-ray diffraction, particle size analyser, zeta potential and scanning electron microscopy, were used to show efficacious synthesis of FeO NPs capped with phytochemicals. Rice seeds primed with FeO NPs at 20 and 40 mg/L efficiently enhanced germination and seedling vigour compared to ferrous sulphate (FeSO4) priming and hydro-primed control. The seeds primed with 20 mg/L FeO NPs showed up to 50% stimulation in biophysical parameters such as root length and dry weight. Substantial stimulation of sugar and amylase content was also reported at the same concentration. The antioxidant enzyme activity was significantly increased as compared to FeSO4 priming and control. Inductively coupled plasma mass spectroscopy (ICP-MS) study was also done for analysis of Fe, Zn, K, Ca, and Mn concentration in seeds. The seed priming technique signifies a comprehensible and innovative approach that could enhance α-amylase activity, iron acquisition, and ROS production, ensuing elevated soluble sugar levels for supporting seedling growth and enhancing seed germination rate, respectively. In this report, phytochemical-capped FeO NPs are presented as a capable nano-priming agent for stimulating the germination of naturally aged rice seeds.

A review of CRISPR associated genome engineering: application, advances and future prospects of genome targeting tool for crop improvement.

The Cas9 nuclease initiates double-stranded breaks at the target position in DNA, which are repaired by the intracellular restoration pathways to eliminate or insert pieces of DNA. CRISPR-Cas9 is proficient and cost-effective since cutting is guided by a piece of RNA instead of protein. Emphasis on this technology, in contrast with two recognized genome editing platforms (i.e., ZFNs and TALENs), is provided. This review evaluates the benefits of chemically synthesized gRNAs as well as the integration of chemical amendments to improve gene editing efficiencies. CRISPR is an indispensable means in biological investigations and is now as well transforming varied fields of biotechnology and agriculture. Recent advancement in targetable epigenomic-editing tools allows researchers to dispense direct functional and transcriptional significance to locus-explicit chromatin adjustments encompassing gene regulation and editing. An account of diverse sgRNA design tools is provided, principally on their target competence prediction model, off-target recognition algorithm, and generation of instructive annotations. The modern systems that have been utilized to deliver CRISPR-Cas9 in vivo and in vitro for crop improvement viz. nutritional enhancement, production of drought-tolerant and disease-resistant plants, are also highlighted. The conclusion is focused on upcoming directions, biosafety concerns, and expansive prospects of CRISPR technologies.

Identification of drought stress-responsive genes in rice (Oryza sativa) by meta-analysis of microarray data.

Meta-analysis provides a systematic access to the previously studied microarray datasets that can recognize several commonsignatures of stresses. Three different datasets of abiotic stresses on rice were used for meta-analysis. These microarray datasets were normalized to regulate data for technical variation, as opposed to biological differences between the samples. A t-test was performed to recognize the differentially-expressed genes (DEGs) between stressed and normal samples. Gene ontology enrichment analysis revealed the functional distribution of DEGs in different stressed conditions. Further analysis was carried out using software RICE NET DB and divided into three different categories: biological process (homoiothermy and protein amino acid phosphorylation), cellular component (nucleus and membrane), and molecular function (zinc ion binding ad DNA binding). The study revealed that 5686 genes were constantly expressed differentially in Oryza sativa (2089 upregulated and 3597 downregulated). The lowest P value (P = 0.003756) among upregulated DEGs was observed for naringenin, 2-oxoglutrate 3-dioxygenase protein. The lowest P value (P = 0.002866816) among the downregulated DEGs was also recorded for retrotransposon protein. The network constructed from 48 genes revealed 10 hub genes that are connected with topological genes. These hub genes are stress responsive genes that may also be regarded as the marker genes for drought stress response. Our study reported a new set of hub genes (reference genes) that have potentially significant role in development of stress tolerant rice.

A comparative screening of abiotic stress tolerance in early flowering rice mutants.

Oryza sativa L. (Rice) a grain crop grown considerably in areas frequented with abiotic stresses has a higher heat and drought tolerance and is deemed a model crop for tolerance studies. Manifold environment testing facilitates recognition of constant genotypes of rice mutants for adverse abiotic stress conditions. Mutants are an imperative genetic reserve which can help as an informative basis of natural disparity. We assessed EMS induced early flowering rice mutants (Control, BM6, BM6´ and BM9) for potential study of stress tolerance under limited water, salinity and high zinc conditions by testing for plant growth (biophysical and biochemical) traits, as well ascytotoxicity and genotoxicity determination assay via MTT and epifluoresence microscopy methods in root tissues of the mutants. Environmental effect was more significant than genotypic contribution on biophysical and biochemical parameters. BM9 mutant was found to be the most stable genotype in tolerance studies among other mutants in artificially created stress environments viz. mannitol (moderated drought), sodium chloride (salinity stress), zinc sulfate (heavy metal stress) and zinc oxide nanoparticles for a time duration. These mutants are a valuable resource for varietal advancements and to determine genes for tolerance to multiple abiotic stresses. To our knowledge this is the first account on validation of manifold abiotic stresses in early flowering rice mutants. This study can additionally assist fastidious detection of stress-tolerance genes in this vital crop.

Inhibitory Mechanism on Combination of Phytic Acid with Methanolic Seed Extract of Syzygium cumini and Sodium Chloride over Bacillus subtilis.

The antibiotic resistance in bacteria responsible for causing community and health care-associated infection displayed a major threat to global health. Use of broad-spectrum antibiotics for the treatment of various ailments poses serious side effects. In the present research, we investigated the combined role of 2% phytic acid with 2% methanolic seed extract of Syzygium cumini and 0.5% sodium chloride for inhibition of Bacillus subtilis and Pseudomonas aeruginosa and found it to be efficient over B. subtilis. The zone of inhibition by present mixture was found to be 2.9 ± 0.0004 and 1.9 ± 0.0006 cm against Bacillus subtilis and P. aeruginosa in comparison to individual component. Mixture was found more potent against B. subtilis and selected for further study. The underlying mechanism involved in inhibitory action of this mixture was determined by Scanning electron microscope, DNA fragmentation and propidium iodide staining. Scanning electron microscopy revealed that inhibition of B. subtilis by this mixture is mainly due to the disruption of bacterial cell membrane, leakage of internal cellular content which ultimately leads to the death of bacterial cells. DNA fragmentation showed apoptotic hallmark through degradation caused by mixture against B. subtilis at various time intervals. Likewise, PI staining also revealed the disruption of bacterial membrane by the mixture as the PI gives fluorescence after binding with DNA. The present study concludes that inhibitory potential of this mixture is mainly due to disruption of bacterial cell membrane, degradation of DNA and creation of pores in the membrane. The mixture could be used for inhibition of food pathogen B. subtilis.

Antimicrobial action of methanolic seed extracts of Syzygium cumini Linn. on Bacillus subtilis.

Phytochemicals of Syzygium cumini are used for the treatment of various diseases as a traditional medicine but the mechanism behind their action is not well reported. Antimicrobial activity of methanolic seed extract of S. cumini was done by agar well diffusion assay on Bacillus subtilis and its zone of inhibition was found to be 20.06 mm in comparison to control having no zone of inhibition. MIC of S. cumini was found to be 0.3 mg/ml. Genomic DNA degradation of B. subtilis reveals apoptosis and FE-scanning electron microscope indicates cell wall cracking on several intervals of time. Results of propidium iodide staining showed few bacterial cells were stained in control; however population of stained cells increased after exposing them for varying period of time. Flow cytometric kinetic data analysis on the membrane permeabilization in bacterial cell showed the significant contribution of antimicrobial potential of the seed extract on antimicrobial-induced permeabilization. In silico analysis revealed two components of S. cumini methanolic extract to be active against four enzymes (PDB ID-1W5D, 4OX3, 3MFD and 5E2F) which are crucial for plasma membrane synthesis in B. subtilis. Moreover lupeol showed highest binding energy for macromolecule 1W5D and 4OX3 forming one hydrogen bond each whereas stigmasterol showed the highest binding energy for macromolecule 3MFD and 5E2F forming four hydrogen bonds and alkyl bonds respectively. It demonstrates that methanolic seed extracts of S. cumini could be used for inhibition of food born infection caused by B. subtilis and also an alternative of prevalent antibiotics.

Isolation and Characterization of Fusarium verticillioides NKF1 for Unsaturated Fatty Acid Production.

Polyunsaturated fatty acid helps to prevent diseases like cardiovascular, inflammation, and cognitive abilities for developmental disorders. The main objective of this research is the screening of polyunsaturated fatty acid producing fungi from soil samples of mangrove from the seashore coastal areas in India. Fusarium verticillioides species showed the presence of saturated and unsaturated fatty acid in the starch yeast-extract medium. Among the representative isolate, F. verticillioides NKF1 was found to grow in a YEP broth medium and produce the maximum lipid. The gas chromatography was used to identify the fatty acids present in fungal strain. Saturated fatty acid such as palmitic acid (C16:0) 0.14/100 g, stearic acid (C18:0) 0.09/100 g, and monounsaturated fatty acid such as oleic acid (C18:1) 0.08/100 g and polyunsaturated fatty acid such as linolenic acid (C18:3ω3) 0.08/100 g were present in significant amount in the fungal strain. Fungal strain F. verticillioides NKF1 was characterized by SEM and molecular characterization by 18S rRNA. The internal transcribed spacer (ITS) sequences were analyzed by 18S rRNA and ITS4 sequences of related fungi were sequenced, and then the data were compared with NCBI database. This newly isolated F. verticillioides NKF1 was found to be a promising culture for the development of an economical method for commercial production of linolenic acid (ω-3 fatty acid).

Crystal structure of 5-(furan-2-yl)-N-phenyl-1,3,4-oxa-diazol-2-amine.

The title compound, C12H9N3O2, was obtained as a cyclized oxa-diazole derivative from substituted thio-semicarbazide in the presence of manganese(II) acetate. The furan ring is disordered over two orientations, with occupancies of 0.76 (2) and 0.24 (2). The dihedral angles between the central oxa-diazole ring and the pendant phenyl ring and furan ring (major disorder component) are 3.34 (18) and 5.7 (6)°, respectively. A short intra-molecular C-H⋯O contact generates an S(6) ring. In the crystal, inversion dimers linked by pairs of N-H⋯N hydrogen bonds generate R 2 (2)[8] loops. The dimers are linked by C-H⋯π and π-π inter-actions [range of centroid-centroid distances = 3.291 (2)-3.460 (8) Å], generating a three-dimensional network.

Hospital based prospective longitudinal clinical and immunologic study of 179 patients of primary anti-phospholipid syndrome.

AIM: To study the clinical and immunological features of primary antiphospholipid syndrome (APS), and to analyze the differences between primary APS and APS associated with autoimmune rheumatic disease (ARD/APS). METHODS: This prospective, longitudinal study, carried out from December 2004 to July 2011 included 179 patients with primary APS and 52 patients of ARD/APS diagnosed as per modified 2006 Sapporo's Criteria. RESULTS: Out of 179 patients of primary APS, 12 were male and 167 were female. The mean age at the time of study entry was 27 ± 4.33 years. Venous thrombosis was noted in 33 (18.43%) patients. Seventeen patients had deep vein thrombosis and 11 (7.19%) had cortical vein and/or cortical sinus thrombosis. Arterial thrombosis was noted in 19 (10.61%) patients, out of which nine had intracranial arterial thrombosis. Thirty-two (17.85%) had recurrent early fetal losses (< 10 weeks) and 97 (54.18%) had late fetal loss (> 10 weeks). Immunoglobulin G (IgG) and IgM aCLA were present in 141 (78.77%) and 32 (17.87%) patients respectively, whereas lupus anticoagulant was present in 99 (55.3%) patients. In patients with bad obstetric outcome, lupus anticoagulant positivity was significantly more prevalent (P < 0.05) than aCLA positivity. Both venous and arterial thrombosis were significantly more common (P < 0.05) in ARD/APS. However, late fetal loss was significantly more prevalent (P < 0.001) in primary APS. CONCLUSION: Primary APS may lead to a variety of clinical manifestations due to venous and/or arterial thrombosis, which at times may be lethal. It is also an important cause of early and late pregnancy loss(es) and other pregnancy morbidities.