Dr. Omar Hussain: Research scholar at National Institute of Technology Srinagar, India

Title/Designation: Dr.
Name: Omar Hussain
Current Role/Designation: Postdoctoral Student
Organization/Institution Details: National Institute of Technology Srinagar
Country: India
Subject Track: Engineering
Key Areas of Expertise: Biomedical Engineering, Biomaterials, Orthopaedic Implant Materials
Award Categories: Emerging Researcher Award

Dr. Omar Hussain is an accomplished biomedical engineer with a PhD from the National Institute of Technology Srinagar, specializing in biomaterials for orthopedic applications. His research primarily focuses on improving the tribological performance of ultra-high molecular weight polyethylene (UHMWPE) composites used in joint replacement devices. With extensive experience in material characterization, surface engineering, and biomechanics, Dr. Hussain combines engineering principles with clinical relevance to develop innovative solutions that enhance implant longevity and patient outcomes. He is passionate about translating research into practical biomedical innovations.

Online Profiles

ORCID Profile Page

Dr. Hussain is actively engaged in academic and research communities and can be contacted at omarhuzzain@gmail.com. He maintains professional profiles on research networking platforms and contributes regularly to scientific journals and conferences. His work is indexed in multiple reputed databases, providing visibility and accessibility to his research findings. Dr. Hussain is open to collaborative projects, consulting roles, and knowledge exchange opportunities within the biomedical engineering field.

Education

Dr. Hussain completed his PhD in Biomedical Engineering at the National Institute of Technology Srinagar, where his dissertation focused on the evaluation and enhancement of the tribological properties of UHMWPE for biomedical applications, particularly cartilage replacement. Prior to his doctorate, he earned a Master of Engineering degree with distinction from SRM University, India, conducting research on stress distribution and biomechanics in the lumbar spine. He holds a Bachelor of Engineering degree in Biomedical Engineering from BHARATH University, India, graduating with distinction and establishing a strong foundation in engineering and medical sciences.

Research Focus

His research explores the intersection of materials science, biomechanics, and tribology to develop advanced composite materials tailored for biomedical implants. Dr. Hussain’s work includes the fabrication of UHMWPE-based composites reinforced with nano and micro-scale additives such as aluminum oxide and graphene nanoplatelets, aimed at improving wear resistance and mechanical stability. He investigates the effects of various bio-fluids, including synovial fluid, on implant materials to better simulate in vivo conditions. His ongoing studies contribute to the optimization of implant designs to reduce wear-related failures and enhance patient mobility.

Experience

Dr. Hussain’s professional journey spans academia and applied biomedical engineering roles. He served as a temporary faculty member in the Department of Biomedical Engineering at NIT Raipur, where he taught courses and mentored students. Earlier, he worked as a biomedical engineer in the Department of Radiological Physics and Bioengineering at SKIMS, contributing to clinical engineering projects. Additionally, he volunteered with Ehsaas Trust International during the COVID-19 pandemic, participating in public health awareness campaigns. His diverse experience underscores his commitment to both education and impactful biomedical research.

Research Timeline & Activities

Between 2016 and 2022, Dr. Hussain’s research at NIT Srinagar was dedicated to developing and characterizing UHMWPE-based biomaterials. He conducted extensive tribological testing under varied lubrication environments to mimic physiological conditions, developed novel hybrid composites incorporating vitamin C and graphene nanoplatelets, and applied statistical optimization methods like Taguchi and Grey Relational Analysis for performance enhancement. His research also involved creating nano and micro-scale surface coatings to improve implant biocompatibility and wear resistance. Throughout this period, he published multiple peer-reviewed articles and presented his findings at international conferences.

Awards & Honors

In recognition of his research excellence and academic potential, Dr. Hussain was awarded a prestigious PhD fellowship in 2016 by the Ministry of Human Resource Development, Government of India. This competitive fellowship supported his doctoral studies and research activities. His work has also been acknowledged through invitations to present at conferences and inclusion in high-impact journals, reflecting his contributions to the field of biomedical materials engineering.

Top Noted Publication

A significant publication from Dr. Hussain’s portfolio is titled “Friction and wear performance evaluation of UHMWPE using Taguchi-based grey approach: A study on the influence of load and bio-serum lubrication,” published in Materials Chemistry and Physics in 2020. This paper presents a comprehensive analysis of how varying load conditions and lubrication with bio-serum affect the wear behavior of UHMWPE, utilizing advanced statistical techniques to optimize material performance. The study provides valuable insights for designing more durable biomedical implants and is frequently cited by researchers working on implant tribology and biomaterials.

• A study of Ti/TaN coating on Ti6Al4V-alloy for orthopaedic implant application
  Transactions of the IMF, 2025-08-22
  DOI: 10.1080/00202967.2025.2541470
  Contributors: Omar Hussain, Shahid Saleem

• Biomaterials for artificial knee joint replacement: a review
  International Journal of Materials Engineering Innovation, 2023
  DOI: 10.1504/IJMATEI.2023.130129
  Contributors: Omar Hussain, Babar Ahmad, Sheikh Shahid Saleem

• Fabrication and tribological behavior of novel UHMWPE/vitamin-C/graphene nanoplatelets based hybrid composite for joint replacement
  Industrial Lubrication and Tribology, 2021-12-28
  DOI: 10.1108/ILT-02-2021-0033
  Contributor: Omar Hussain

• Biotribological performance of medical-grade UHMW polyethylene-based hybrid composite for joint replacement
  Polymers and Polymer Composites, 2021-11
  DOI: 10.1177/09673911211058088
  Contributor: Omar Hussain

• Tribological performance of biomedical grade UHMWPE/nano-Al₂O₃/Vitamin-C hybrid composite for cartilage replacements
  Materials Letters, 2021-05
  DOI: 10.1016/j.matlet.2021.129515
  Contributors: Omar Hussain, Babar Ahmad, Shahid Saleem

Strengths for Emerging Researcher Award — Dr. Omar Hussain

1. Robust Interdisciplinary Background and Research Focus
   Dr. Hussain combines expertise in Biomedical and Mechanical Engineering, demonstrated through his Ph.D. research on UHMWPE composites for biomedical implants, bridging materials science and clinical applications to improve patient outcomes.

2. Strong Research Productivity with High-Quality Publications
   He has published multiple peer-reviewed articles in reputed international journals on biomaterials and tribology, showcasing innovative approaches in implant material development and wear performance, reflecting his active contribution to the biomedical engineering field.

3. Ph.D. Fellowship and Recognition
   Recipient of the prestigious MHRD fellowship (2016) during his doctoral studies, highlighting his academic excellence and the potential of his research contributions at the national level.

4. Hands-on Experience in Clinical and Academic Settings
   With experience as a biomedical engineer in a hospital environment (SKIMS) and as a temporary faculty member at NIT Raipur, Dr. Hussain has a practical understanding of medical device applications and a commitment to teaching and mentoring.

5. Innovative Research on Biomedical Implant Materials and Coatings
   His work on nano and micro-level coatings, alongside UHMWPE-based composite development under bio-serum and synovial fluid conditions, addresses critical challenges in orthopedic implant durability and biocompatibility, advancing personalized healthcare solutions.