Introduction: Dental implants have been used to replace missing teeth and many developments have been introduced over the last two decades. Both academic and industry researchers have invested substantial amounts in research and development to improve the implant materials, designs, surface treatments, implant-abutment connections, and related surgical procedures. In this highly competitive field, there are two important issues to be analyzed and evaluated: 1. More efficient methods are needed to analyze the fast increasing publications and patents in order to predict the R&D trends of the implant industry and promote more advanced clinical solutions including methods, materials, and devices. 2. Many implant designs and surgical protocols claimed to improve implant survival rate or implant stability at the implant site without adequate evaluation of bone quality. Effectiveness of these claims are questionable due to controversies in defining the bone quality and implant stability. Many clinicians evaluate bone quality by using tactile feedback while drilling the bone. Evaluation discrepancy between clinicians has become a confounding factor across clinical trials. Implant initial stability is an important predictor of implant survival. Two non-invasive clinical methods are frequently used to evaluate implant stability: insertion torque (IT) during implant placement and natural frequency analysis or “implant stability quotient” (ISQ) after implant placement. There is no research demonstration which method best represents “true implant initial stability.” Purposes, Materials and Methods 1. Using a cooperative study including researchers of engineering informatics and dental implant specialist (domain experts), a knowledge centric methodology for dental implant technology assessment was introduced to speed the process of patent analysis. This study included a domain specific ontology-based patent analysis of dental implant connections and a meta‐analysis of the related clinical trials. Text mining, extracting key phrases, creating the domain ontology, and analyzing clusters of patents related to implant connection were reviewed. Relations between implant connections and survival rate and marginal bone loss were evaluated using a meta-analysis of related clinical trials retrieved using the patent key phrases. 2. Six oral surgeons and 59 general dentists were invited to evaluate the bone quality of artificial bone blocks fabricated from polyurethane foam blocks (SawbonesR) consisting of different densities. The bone density and quality was evaluated using the tactile feedback obtained by drilling with a 2mm twist drill. A visual analog scale value of bone density and bone quality classification were recorded for each test block. 3. The effects of implant design and bone quality on insertion torque, implant stability quotient, and insertion energy (IE) were studied. Test blocks were used to simulate low or low-to-medium density cancellous bone with and without a thin cortical layer. Four different implants were placed in accordance with the manufacturer’s instructions. The IT and ISQ were recorded for every 0.5-mm of inserted length during implant insertion, and the IE was calculated. Results, Discussions and Conclusions 1. Twenty patents related to implant connection were collected from USPTO and divided into four technology clusters. The key phrases from the patents were used for clustering and to search for related clinical trials and research publications. Platform switching was the key phrase with the highest frequency in related clinical trials. Six trials were included for meta-analysis to evaluate the effect of platform switching on implant survival rate and marginal bone loss. This methodology can be applied to a wide variety of medical and dental devices to link successful clinical trials and their effectiveness to patent designs and innovations in order to provide a new means to qualify patent value. 2. Discrepancy in evaluating bone quality exists among clinicians. Experienced oral surgeons evaluate bone quality more accurately than general dentists. Therefore, it is necessary to develop a calibration system to decrease the measurement discrepancy between dental professionals. 3. The presence of cortical bone and implant designs significantly affect dynamic IT profiles during implant insertion, while not similarly affecting ISQ. Future studies are needed to explore parameters representing implant stability and to modify surgical protocols to improve the ISQ and IT.