Research Activities

Physical and mechanical property analysis of materials models, surgical guides, restorative materials, and prosthetic devices fabricated by machining and printing. Accuracy of machined and printed restorations and prosthetic devices.

Analysis of mechanical properties, physical properties, and optical properties of zirconia, glass ceramics, and felspathic ceramics. Development of new bioactive interpenetrating phase materials for machining applications.

Development and testing of indirect and direct polymer matrix materials for permanent restorations, fixed and removable prosthetic devices. Impact resistance of mouthguard materials.

Biocompatibility, osteogenic potential, and material properties of titanium and zirconia implant materials with variable composition and surface finish.

Analysis of sealing ability, mechanical and physical properties of conventional and bioactive sealers. Fatigue and mechanical properties of files. Effectiveness of endodontic debridement systems such as the Gentlewave.

Analysis of aligner materials and development and testing of novel bracket materials.

Effectiveness of fluoride containing materials in reversing and preventing enamel demineralization.

Effect of laser treatment on tooth structure and debridement of root canals.

Dr. Yuwei Fan’s research interests are in the area of biomineralization, enamel regeneration, electron microanalysis, material analysis, digital dentistry technology, functional biomaterials, and restorative material clinical performance. Recent studies include comparing success rates between novel CAD/CAM milled single crowns and gold crowns, measuring the accuracy of 3D printed prostheses made using different methods, fabricating novel bioactive restorative materials, and regenerating a synthetic enamel crystal layer similar to natural enamel on tooth surfaces to treat dental diseases.

This is a research field pioneered by Dr. Lee Chou with his groundbreaking discovery that biomaterials’ surface chemistry and surface topography are the signals sensitively and selectively regulating the gene expression and activity of functional proteins. These discoveries changed the traditional theory of biomaterial inertness. Dr. Chou’s proposal for a “Biomaterials’ Molecular Biocompatibility Profile” catalyzed the development of third-generation biomaterials and influenced the USA federal white paper “Materials Genome Initiative” issued by President Obama in 2011.

The Molecular Biocompatibility Lab was established in 1994. Having over 60 students graduated from this lab, the research projects have covered the arears including creations and designs of novel osteogenic materials and odontogenic materials, novel technologies for biomaterials safety and efficacy evaluations, cytotoxicity and genotoxicity studies of nanomaterials, and tissue engineering.

3D biodegradable, biomimetic materials and modifying their properties to induce + improve osteoblastic differentiation for bone regeneration.

Modification of physical surface roughness and chemistry to modulate macrophage polarization to mitigate the chronic inflammatory response and improve implant survival outcomes.

The Laboratory for Applied Biomechanics is pioneering research at the intersection of biomechanics, materials science, and clinical practice. Our lab explores how biomechanical forces affect both macro-scale and cellular dynamics, with the aim of improving surgical outcomes and patient quality of life. Using advanced computational modeling, in vitro studies, and collaborations across disciplines, we focus on both postural disturbances caused by dental interventions and innovative tissue-engineering solutions for craniofacial reconstruction.

Our lab investigates how dental treatments and restorations can lead to postural disturbances by altering the functional relationship between the stomatognathic system and whole-body posture. Recent studies focus on neuromuscular pathways and sensory integration mechanisms that link cranio-cervical posture to balance and gait. This research is particularly significant as we explore the aging population’s needs for improved balance and stability post-surgery, aiming to design targeted interventions that prevent falls and enhance mobility.

The development of functional/fast-healing bone grafts for craniofacial reconstruction is another focus of the Laboratory. These bioinspired, biocompatible and bioresorbable scaffolds are engineered to fit complex bone defects and are designed to promote osteogenic differentiation. We are improving the mechanical properties of these scaffolds through innovative compositions such as the inclusion of piezoelectric materials, while enhancing their structural integrity to support load-bearing applications. This research aims to address the clinical challenges of intraoral bone regeneration, improving outcomes and reducing complications associated with craniofacial surgeries