Research Interests 

1. My core research interests focus on the technology development of implantable devices with strong translational and clinical relevance. These include engineering proprioceptive and neurofunctional implant systems for craniofacial and orthopedic applications, advancing regenerative biomaterials, developing novel coatings, biodegradable scaffolds, and surface-engineered implants for bone and neural tissue regeneration, and neural–implant interface engineering aimed at peripheral nerve integration and sensory restoration in implantable devices. 

2. My work further encompasses surgical bioengineering approaches, including implant design, modified surgical  protocols, surgical anatomy–guided strategies, and experimental surgical methodologies to modulate osseointegration and promote neurointegration. 

3. Additional research domains include stem cell–based regenerative strategies, mechanobiology, and biomaterial-driven tissue responses; the development of sensory-enabled prosthetic and implant systems capable of transmitting physiologically meaningful mechanical and neural signals; and the use of preclinical animal models, experimental microsurgical techniques, and translational implant research. 

4. Functional validation is performed using advanced neurodiagnostic approaches, including fMRI- and EEG-based neurofunctional assessment frameworks. Collectively, my research advances biomaterials and tissue engineering strategies within a translational clinical context, bridging fundamental bioengineering innovations with patient-centered therapeutic applications. 

Completed Projects

1. Osteogenic Nanofibrous Implant Interfaces

Project: Osteogenic nanofibres–coated titanium implants for improved osseointegration
Focus: Bioactive nanofibrous coatings to enhance bone–implant integration and accelerate functional stability in endosseous implants.
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2. Neurogenic Peri-Implant Tissue Engineering

Project: Neurogenesis in orthotopically installed peri-implant tissue for inducing proprioceptive features
Focus: Engineering peri-implant microenvironments to promote neural regeneration and restore proprioceptive feedback at the implant–tissue interface.
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3. Sensory-Enabled Dental Implant Surgery

Project: Optimizing surgical protocols in advanced dental implant prototypes to enhance proprioceptive integration
Focus: Surgical–bioengineering strategies to preserve native neural elements and enable functional sensory integration in next-generation dental implants.
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