Your search keyword '"Houshyar, Shadi"' showing total 18 results

1. Preparation and performances of coated polypropylene hernia mesh with natural biomaterials

Author

Yu, Shuang, Shi, Wentao, Houshyar, Shadi, Wang, Xin, and Ma, Pibo

Published

2021

2. An octagonal-shaped conductive HC12 & LIBERATOR-40 thread embroidered chipless RFID for general IoT applications

Author

Khan, Muhammad Usman Ali, Raad, Raad, Foroughi, Javad, Raheel, M. Salman, and Houshyar, Shadi

Published

2021

3. Polypropylene-nanodiamond composite for hernia mesh

Author

Houshyar, Shadi, Sarker, Avik, Jadhav, Amit, Kumar, G. Sathish, Bhattacharyya, Amitava, Nayak, Rajkishore, Shanks, Robert A., Saha, Tanushree, Rifai, Aaqil, Padhye, Rajiv, and Fox, Kate

Published

2020

4. Optimisation of grafted phosphorylcholine-based polymer on additively manufactured titanium substrate for hip arthroplasty

Author

Ghosh, Subir, Abanteriba, Sylvester, Wong, Sherman, Brkljača, Robert, and Houshyar, Shadi

Published

2019

5. Nanodiamond/poly-ε-caprolactone nanofibrous scaffold for wound management

Author

Houshyar, Shadi, Kumar, G. Sathish, Rifai, Aaqil, Tran, Nhiem, Nayak, Rajkishore, Shanks, Robert A., Padhye, Rajiv, Fox, Kate, and Bhattacharyya, Amitava

Published

2019

6. Polyamide-nanodiamond filament

Author

Houshyar, Shadi, Sathish Kumar, G., Padhye, Rajiv, Shanks, Robert A., and Bhattacharyya, Amitava

Published

2021

7. Selective laser melted titanium alloys for hip implant applications: Surface modification with new method of polymer grafting.

Author

Ghosh, Subir, Abanteriba, Sylvester, Wong, Sherman, and Houshyar, Shadi

Subjects

TOTAL hip replacement, ARTIFICIAL implants, TITANIUM alloys, TRANSPLANTATION of organs, tissues, etc., MELTING, X-ray spectroscopy

Abstract

Abstract A significant number of hip replacements (HR) fail permanently despite the success of the medical procedure, due to wear and progressive loss of osseointegration of implants. An ideal model should consist of materials with a high resistance to wear and with good biocompatibility. This study aims to develop a new method of grafting the surface of selective laser melted (SLM) titanium alloy (Ti-6Al-4V) with poly (2-methacryloyloxyethyl phosphorylcholine) (PMPC), to improve the surface properties and biocompatibility of the implant. PMPC was grafted onto the SLM fabricated Ti-6Al-4V, applying the following three techniques; ultraviolet (UV) irradiation, thermal heating both under normal atmosphere and UV irradiation under N 2 gas atmosphere. Scanning electron microscopy (SEM), 3D optical profiler, energy-dispersive X-ray spectroscopy (EDS), X-ray photoelectron spectroscopy (XPS), and Fourier transform infrared spectroscopy (FTIR) were used to characterise the grafted surface. Results demonstrated that a continuous PMPC layer on the Ti-6Al-4V surface was achieved using the UV irradiation under N 2 gas atmosphere technique, due to the elimination of oxygen from the system. As indicated in the results, one of the advantages of this technique is the presence of phosphorylcholine, mostly on the surface, which reveals the existence of a strong chemical bond between the grafted layer (PMPC) and substrate (Ti-6Al-4V). The nano-scratch test revealed that the PMPC grafted surface improves the mechanical strength of the surface and thus, protects the underlying implant substrate from scratching under high loads. Graphical abstract fx1 [ABSTRACT FROM AUTHOR]

Published

2018

8. Sustainable reuse of fashion waste as flame-retardant mattress filing with ecofriendly chemicals.

Author

Nayak, Rajkishore, Houshyar, Shadi, Patnaik, Asis, Nguyen, Long TV., Shanks, Robert A., Padhye, Rajiv, and Fegusson, Mac

Subjects

*FIRE resistant polymers, *WASTE recycling, *SUSTAINABLE fashion, *POLYESTER fibers, *REFUSE containers, *MATTRESSES, *FILLER materials

Abstract

There has been increased attention from global organisations and fashion brands on the problems associated with fashion waste. This study sought to recycle fashion waste clothing collected from Australian consumers into fibre blends to reuse as a filling material in children's mattresses. The fibre blends were quantitatively analysed for composition. Then the fibers were treated with eco-friendly flame-retardant finishes, and the flame retardancy was evaluated by limiting oxygen index and electrical burner test. The treated fibres were further characterised by thermogravimetric analysis, Fourier-transform infrared, and X-ray diffraction. The quantitative fibre blend analysis indicated that the predominant fibres used in the clothing of Australian consumers are cotton, followed by polyester. The application of green flame-retardant finishes aided in the improvement of the flame retardancy to the standard level, as shown by the limiting oxygen index and electrical burner test. It was also observed that the flame-retardant finish increased the thermal stability of the fibre blend, which delayed and reduced the thermal degradation and decomposition of the mattress filling. Furthermore, the presence of the flame-retardant finish was determined by the Fourier-transform infrared, but there was no change to the chemical composition of the treated fibre blend samples. Picture of fashion waste fibres trated with flame retardant finish. Image 1096893 • Recycled waste clothing reuses as filling material in children's mattresses. • Fashion waste in landfill can be reduced by extracting fibres for reuse. • Post-consumer waste clothing predominantly consists cotton fibre. • Ecofriendly chemical finishes improved flame retardancy. [ABSTRACT FROM AUTHOR]

Published

2020

9. Effect of nanocomposite coating and biomolecule functionalization on silk fibroin based conducting 3D braided scaffolds for peripheral nerve tissue engineering.

Author

Pillai, Mamatha M., Kumar, G Sathish, Houshyar, Shadi, Padhye, Rajiv, and Bhattacharyya, Amitava

Subjects

NERVE tissue, SILK fibroin, PERIPHERAL nervous system, TISSUE engineering, TISSUE scaffolds, COMPOSITE coating, DYNAMIC mechanical analysis

Abstract

In this work, the effects of carbon nanofiber (CNF) dispersed poly-ε-caprolactone (PCL) nanocomposite coatings and biomolecules functionalization on silk fibroin based conducting braided nerve conduits were studied for enhancing Neuro 2a cellular activities. A unique combination of biomolecules (UCM) and varying concentrations of CNF (5, 7.5, 10% w/w) were dispersed in 10% (w/v) PCL solution for coating on degummed silk threads. The coated silk threads were braided to develop the scaffold structure. As the concentration of CNF increased in the coating, the electrical impedance decreased up to 400 Ω indicating better conductivity. The tensile and dynamic mechanical property analysis showed better mechanical properties in CNF coated samples. In vitro cytocompatibility analysis proved the non-toxicity of the developed braided conduits. Cell attachment, growth and proliferation were significantly enhanced on the biomolecule functionalized nanocomposite coated silk braided structure, exhibiting their potential for peripheral nerve regeneration and recovery. Unlabelled Image • The effect of biomolecule functionalized nanocomposite coating on silk fibroin based braided nerve conduits was studied for enhancing Neuro 2a cellular activities. • This is the first study on Silk- poly-ε-caprolactone–carbon nanofiber braided 3D constructs for bridging damaged nerve gaps. • Slow degradation and non-toxicity of degradation products were confirmed. • The combined effect of unique combination of biomolecules and carbon nanofiber on cell proliferation ended up with an advanced nerve conduit compared to pure silk. • Physical characterization and cell culture studies proved the potential of such nanocomposite coated functionalized braided scaffolds for nerve regeneration. [ABSTRACT FROM AUTHOR]

Published

2020

10. Performance analysis of grafted poly (2-methacryloyloxyethyl phosphorylcholine) on additively manufactured titanium substrate for hip implant applications.

Author

Ghosh, Subir, Abanteriba, Sylvester, Wong, Sherman, and Houshyar, Shadi

Subjects

TOTAL hip replacement, GRAFT copolymers, YOUNG'S modulus, WEAR resistance, TITANIUM

Abstract

The incidence of total hip arthroplasty (THA) has been evidently growing over the last few decades. Surface modification, such as polymer grafting onto implant surfaces using poly (2-methacryloyloxyethyl phosphorylcholine) (PMPC), has been gaining attention due to its excellent biocompatibility and high lubricity behaviour resulting in reducing surgical recurrence number and increasing implant lifetime. Investigating thermal stability and mechanical properties of the grafted polymer is, therefore, extremely important as these properties define the failure mechanism of implants. This study focuses on optimising monomer concentration to achieve the best physical, thermal and mechanical properties of the grafted additively manufactured titanium (Ti6Al4V) implants. Three different concentration of monomers, 0.4 M, 0.6 M and 0.8 M, were investigated, and grafted implants were characterised. The results from thermal analysis confirmed that the PMPC polymer is thermally stable for implant applications regardless of the monomer concentrations. A significant reduction in Young's modulus of polymer grafted samples (33.2–42.9%), in comparison with untreated Ti6Al4V samples and consequent improvement of wear resistance and elasticity behaviour, proved the potentiality of polymer films for implant applications. In summary, polymer grafted implant prepared with 0.6 M monomer concentration showed the optimal thermal, physical and wear resistance properties. • Poly (2-methacryloyloxyethyl phosphorylcholine) (PMPC) is thermally stable for physiological condition of hip joints. • Optimal monomer concentration improved surface properties of PMPC grafted 3D implant. • PMPC grafted implant reduced Young's modulus of the implant surface, which is closer to property of human bone.. • Ti6Al4V exhibited the enhanced elasticity behavior after polymer grafting. • PMPC grafting address the main issue in hip implant by improving wear resistance led in longer lifetime of the implant. [ABSTRACT FROM AUTHOR]

Published

2019

11. Enhancement of concrete performance and sustainability through incorporation of diverse waste carpet fibres.

Author

Gamage, Nayanatara, Gunasekara, Chamila, Law, David W., Houshyar, Shadi, Setunge, Sujeeva, and Cwirzen, Andrzej

Abstract

Carpet fibres have demonstrated the potential to mitigate early-age cracking and improve tensile properties in concrete. However, a detailed analysis of the varied types of standard carpet fibres in reinforced concrete has been lacking. This study aims to bridge this gap by investigating the performance of concrete reinforced with widely used waste carpet fibres, namely Nylon, Polypropylene, Polytrimethylene terephthalate, and Polyester. The study employs fibres at 0.3 % and 0.5 % volume fractions with a 12 mm length. The research examines mechanical properties, shrinkage and cracking behaviour, pore structure, microstructure, and the ITZ. Results show that 0.3 % fibre volume yielded optimal performance based on GRA analysis. All fibre types reduced shrinkage compared to the control with no fibres. Nylon T1 at 0.3 % achieved a 22.3 % reduction at 90 days. Furthermore, fibre inclusion enhanced flexural and splitting tensile strengths up to 12 % and 39 % respectively due to fibre bridging, pore refinement, and reduced porosity. Notably, individual fibre mechanical properties influenced concrete performance significantly. Hydrophilic fibres exhibited a thinner 10 µm ITZ compared to 15 µm for hydrophobic fibres, contributing to denser interfacial regions and improved bonding. This study demonstrates the potential of carpet fibre-reinforced concrete as a sustainable solution, offering enhanced mechanical properties, shrinkage mitigation, and effective utilization of carpet waste, addressing critical issues in construction and waste management sectors. • PTT T1 (0.5 %) had highest flexural strength, 11.8 % higher at 28 days, than control. • Compressive strength and shrinkage reduction were optimum with 0.3 % fibre volume. • Nylon T1 fibres (0.3 %) reduced shrinkage by 22.3 % at 90 days compared to the control. • Nylon T1(0.3 %) had the lowest porosity, 81.12 % lower than the control at 28 days. • Hydrophobic fibres had an ITZ of 15 µm, while hydrophilic fibres had an ITZ of 10 µm. [ABSTRACT FROM AUTHOR]

Published

2024

12. Shrinkage induced crack control of concrete integrating synthetic textile and natural cellulosic fibres: Comparative review analysis.

Author

Gamage, Nayanatara, Patrisia, Yulin, Gunasekara, Chamila, Law, David W., Houshyar, Shadi, and Setunge, Sujeeva

Subjects

*SYNTHETIC fibers, *NATURAL fibers, *SYNTHETIC textiles, *CRACKING of concrete, *CONCRETE curing, *CONCRETE durability

Abstract

Shrinkage cracks pose significant challenges to the long-term durability of concrete structures, and it can be effectively address by incorporating various types of fibres. Synthetic textile fibres show a significant 10–50 % shrinkage reduction, while natural cellulosic fibres achieve a comparable 5–30 % reduction. This improvement is attributed to the bridging and anchorage effects between fibres and the cement matrix, enhancing overall concrete performance. However, the factors such as fibre length, diameter, volume fraction and characteristics have significant effect on shrinkage performance. This paper aims to present a comprehensive analysis of these critical mechanisms and factors that impact the shrinkage behaviour in both synthetic textile and natural cellulosic fibre-reinforced concrete. The inclusion of fibres creates a three-dimensional fibre matrix within the concrete that provide an internal effect to restrain the absorb water and it reduce the shrinkage of the concrete. Moreover, the presence of fibres introduces a secondary reinforcing mechanism to release tension during the drying process, thereby preventing crack propagation. The highly porous nature of the cellulose structure enhances the porosity of the concrete, creating cross-linked pathways for water evaporation. However, pre wetted cellulose fibre mitigates drying shrinkage by providing internal curing of the concrete. Furthermore, various physical, chemical, and combined surface modification methods have been used to improve the properties of natural fibres. • Shrinkage, cracks in synthetic and natural cellulosic fibre concrete were discussed. • Synthetic fibres show 10–50 % shrinkage reduction while cellulose give 5–30 %. • Bridging and anchorage effect between fibres and matrix cause shrinkage reduction. • Fibre volume fraction is a key factor for shrinkage and crack behaviour in concrete. • Fibre dimensions, strength, modulus, water interaction impact shrinkage and cracks. [ABSTRACT FROM AUTHOR]

Published

2024

13. Peer status in an ethnic context: Associations with African American adolescents' ethnic identity

Author

Rock, Patrick F., Cole, Daphne J., Houshyar, Shadi, Lythcott, Mawiyah, and Prinstein, Mitchell J.

Subjects

*RACIAL identity of African Americans, *SOCIAL status, *PEERS, *AFRICAN American teenagers, *ETHNICITY, *NUMERICAL analysis, *SOCIOMETRY, *CENTRALITY

Abstract

Abstract: This investigation examined the association between ethnic identity centrality and peer status for African American adolescents who represented a sizable proportion, yet numerical minority within a high school context. Initial analyses indicated that a traditional sociometric nomination procedure did not adequately characterize peer status for African American adolescents. A modified nomination procedure varying the ethnicity of nominators yielded measures of African American adolescents'' peer acceptance/rejection and perceived popularity as rated by African American or European American peers. Results suggest that high levels of peer acceptance and popularity as rated by African American peers were associated with high ethnic identity centrality; however, acceptance and popularity as rated by European American peers were unrelated to ethnic identity centrality among African American adolescents. Findings suggest the importance of examining peer status of African American adolescents with consideration given to ethnicity as a relevant context. [Copyright &y& Elsevier]

Published

2011

14. Synthesis of two-component injectable polyurethanes for bone tissue engineering

Author

Bonzani, Ian C., Adhikari, Raju, Houshyar, Shadi, Mayadunne, Roshan, Gunatillake, Pathiraja, and Stevens, Molly M.

Subjects

*POLYURETHANES in medicine, *POLYMERS, *BONES, *TISSUE engineering

Abstract

Abstract: The advent of injectable polymer technologies has increased the prospect of developing novel, minimally invasive arthroscopic techniques to treat a wide variety of ailments. In this study, we have synthesised and evaluated a novel polyurethane-based injectable, in situ curable, polymer platform to determine its potential uses as a tissue engineered implant. Films of the polymers were prepared by reacting two pentaerythritol-based prepolymers, and characterised for mechanical and surface properties, and cytocompatibility. This polymer platform displayed mechanical strength and elasticity superior to many injectable bone cements and grafts. Cytotoxicity tests using primary human osteoblasts, revealed positive cell viability and increased proliferation over a period of 7 days in culture. This favourable cell environment was attributed to the hydrophilic nature of the films, as assessed by dynamic contact angle (DCA) analysis of the sample surfaces. The incorporation of β-TCP was shown to improve mechanical properties, surface wettability, and cell viability and proliferation, compared to the other sample types. SEM/EDX analysis of these surfaces also revealed physicochemical surface heterogeneity in the presence of β-TCP. Based on preliminary mechanical analysis and cytotoxicity results, these injectable polymers may have a number or potential orthopaedic applications; ranging from bone glues to scaffolds for bone regeneration. [Copyright &y& Elsevier]

Published

2007

15. Repurposing of blended fabric waste for sustainable cement-based composite: Mechanical and microstructural performance.

Author

Tran, Nghia P., Gunasekara, Chamila, Law, David W., Houshyar, Shadi, and Setunge, Sujeeva

Subjects

*MORTAR, *BLENDED textiles, *SUSTAINABLE fashion, *RECYCLED products, *CEMENT composites, *POROSITY

Abstract

• Hydrophilic fabric fibres refine the pore structure of cementitious matrices. • Hybrid hydrophobic and hydrophilic fibres counterbalance the pore-refining effects. • Fabric waste fibres suppress the crack propagation and mitigate the quantity of cracks. • Hybrid fabric fibres significantly reduces the shrinkage of cementitious composites. • Blended fabric waste fibres can improve strength properties of cement-based materials. In this study, the strength properties, shrinkage and microstructures of mortar incorporating blended fabric fibres were characterised via X-ray micro CT and nanoindentation. Three different hybrid recycled fabric fibres, namely Kevlar/Nomex, Kevlar/Nylon and Nomex/Nylon fibres were investigated at three different blend ratios (2:1, 1:1, and 1:2). The fibre content was maintained at 0.3 % for all mixes. The findings indicated that the optimum blend ratio for hybrid fabric fibres is 1:1. At this optimum fibre blend ratio, an enhancement by 2.7 %, 4.8 % and 5.9 % in compressive strength, together with 9.8 %, 12 % and 13.4 % in flexural strength of mortar are recorded, corresponding to the inclusion of hybrid Nomex/Nylon, Kevlar/Nomex and Kevlar/Nylon fibres respectively. Kevlar/Nomex fibres display no effect in drying shrinkage mitigation, irrespective of blend ratios. In contrast, Kevlar/Nylon and Nomex/Nylon fibres result in reducing 180-day shrinkage rates by up to 13.9 % and 11 % respectively. The hybrid fabric fibres were found to refine the pore network, especially the highly hydrophilic Kevlar/Nomex fibres. Also, an increase in curing days from 7 to 90 days densifies the microstructure near the fibre-matrix interface due to the growth of hydration products (LD/HD C S H and CH). These research findings can open the pathway for utilising textile waste in landfill as reinforcing members for cementitious matrices toward sustainable building and construction. [ABSTRACT FROM AUTHOR]

Published

2023

16. Microstructural characterisation of cementitious composite incorporating polymeric fibre: A comprehensive review.

Author

Tran, Nghia P., Gunasekara, Chamila, Law, David W., Houshyar, Shadi, and Setunge, Sujeeva

Subjects

*CEMENT composites, *POLYMERIC composites, *FIBERS, *POLYVINYL alcohol, *REINFORCED concrete, *HIGH temperatures

Abstract

• The inclusion of PP, PE, and PVA fibres increases total porosity of cementitious matrices. • Hydrophilic fibres tend to reduce the average pore size of cementitious matrices. • Pore refinement effect is pronounced with the inclusion of microfibres. • Thermal expansion of fibres initiates cracks and releases pressure at elevated temperatures. • High melting viscosity of HDPE inhibits vapour transport and show less spalling mitigation. Synthetic fibres such as polypropylene (PP), polyvinyl alcohol (PVA), and polyethylene (PE) in both virgin and recycled forms have been widely employed in cementitious composites. Apart from providing bridging action for absorbing stress-induced energy, the addition of polymeric fibres also changes the pore systems in the microstructure of cementitious materials. This paper reviews the microstructure changes of cementitious composite incorporating these three polymeric fibres under both ambient and high-temperature condition. The microstructure of polymeric fibre reinforced concrete is characterised by higher porosity than plain concrete. The use of hydrophilic PVA fibres with microfibres induces pore-refining effects. At elevated temperature PP, PVA and low-density PE (LDPE) exhibit good spalling resistance in concrete due to the formation of microcracks and empty channels left by melted fibre. However, high-density PE (HDPE) fibre is ineffective in mitigating the increased vapour pressure in concrete due to a low coefficient of thermal expansion and high viscosity. Furthermore, to achieve well-balanced interfacial properties, physical/chemical surface modification is necessitated. The introduction of reactive functional groups into the polymer chain of hydrophobic PP and PE fibre significantly enhance fibre-matrix interaction in strengthening interfacial properties with cement paste. Whereas, neutralising hydroxyl functional groups in the PVA polymer chain counteracts extreme delamination or fibrillation of polar PVA fibre when they interact with the cement matrix. With surface modification, the possibility of premature rupture of PVA fibre can be minimised, while improving the transfer of stress-induced energy between the cement matrix and the fibre. [ABSTRACT FROM AUTHOR]

Published

2022

17. Biodegradable injectable polyurethanes: Synthesis and evaluation for orthopaedic applications

Author

Adhikari, Raju, Gunatillake, Pathiraja A., Griffiths, Ian, Tatai, Lisa, Wickramaratna, Malsha, Houshyar, Shadi, Moore, Tim, Mayadunne, Roshan T.M., Field, John, McGee, Margaret, and Carbone, Tania

Subjects

*BIODEGRADABLE plastics, *POLYURETHANES, *TISSUE engineering, *ORTHOPEDIC implants, *BONE growth

Abstract

Abstract: Biodegradable polyurethanes offer advantages in the design of injectable or preformed scaffolds for tissue engineering and other medical implant applications. We have developed two-part injectable prepolymer systems (prepolymer A and B) consisting of lactic acid and glycolic acid based polyester star polyols, pentaerythritol (PE) and ethyl lysine diisocyanate (ELDI). This study reports on the formulation and properties of a series of cross linked polyurethanes specifically developed for orthopaedic applications. Prepolymer A was based on PE and ELDI. Polyester polyols (prepolymer B) were based on PE and dl-lactic acid (PEDLLA) or PE and glycolic acid (PEGA) with molecular weights 456 and 453, respectively. Several cross linked porous and non-porous polyurethanes were prepared by mixing and curing prepolymers A and B and their mechanical and thermal properties, in vitro (PBS/37°C/pH 7.4) and in vivo (sheep bi-lateral) degradation evaluated. The effect of incorporating β-tricalcium phosphate (β-TCP, 5microns, 10wt.%) was also investigated. The cured polymers exhibited high compressive strength (100–190MPa) and modulus (1600–2300MPa). β-TCP improved mechanical properties in PEDLLA based polyurethanes and retarded the onset of in vitro and in vivo degradation. Sheep study results demonstrated that the polymers in both injectable and precured forms did not cause any surgical difficulties or any adverse tissue response. Evidence of new bone growth and the gradual degradation of the polymers were observed with increased implant time up to 6months. [Copyright &y& Elsevier]

Published

2008

18. Brain-Derived Neurotrophic Factor–5-HTTLPR Gene Interactions and Environmental Modifiers of Depression in Children

Author

Kaufman, Joan, Yang, Bao-Zhu, Douglas-Palumberi, Heather, Grasso, Damion, Lipschitz, Deborah, Houshyar, Shadi, Krystal, John H., and Gelernter, Joel

Subjects

*CHILD abuse, *ABUSED children, *AFFECTIVE disorders in children, *DEPRESSION in children, *SEROTONIN

Abstract

Background: Child abuse and genotype interact to contribute to risk for depression in children. This study examined gene-by-gene and gene-by-environment interactions. Methods: The study included 196 children: 109 maltreated and 87 nonmaltreated comparison subjects. Measures of psychiatric symptomatology and social supports were obtained using standard research instruments, and serotonin transporter (5-HTTLPR) (locus SLC6A4) and brain-derived neurotrophic factor (BDNF) (variant val66met) genotypes were obtained from saliva-derived DNA specimens. Population structure was controlled by means of ancestral proportion scores computed based on genotypes of ancestry informative markers in the entire sample. Results: There was a significant three-way interaction between BDNF genotype, 5-HTTLPR, and maltreatment history in predicting depression. Children with the met allele of the BDNF gene and two short alleles of 5-HTTLPR had the highest depression scores, but the vulnerability associated with these two genotypes was only evident in the maltreated children. A significant four-way interaction also emerged, with social supports found to further moderate risk for depression. Conclusions: To the best of our knowledge, this is the first investigation to demonstrate a gene-by-gene interaction conveying vulnerability to depression. The current data also show a protective effect of social supports in ameliorating genetic and environmental risk for psychopathology. [Copyright &y& Elsevier]

Published

2006