Temporary intraoral skeletal anchorage devices (TISADs) have become a vital tool in modern orthodontics due to their remarkable capabilities. Improvement of treatment efficiency, redundancy of the patient’s compliance, and performance of complex tooth movements previously unobtainable without apparent side effects are some paramount advantages of TISAD use. However, we must recognize the most significant factor limiting their efficacy: premature loss of stability. The reported microscrew success rates range from 75.4% to 94.4%, indicating that approximately 1 of 10 devices becomes mobile and cannot serve as the anchorage enabling achievement of the treatment goal. Failure of a TISAD requires at best its reinsertion resulting in additional surgery and increases treatment cost and duration; in complex cases, microimplant instability may imply more severe consequences: eg, inability to intrude molars and need for referral for orthognathic surgery.

Investigation of both the patient’s characteristics and the design and management of the microimplants in terms of their impact on TISAD stability showed various failure risk factors such as hyperdivergent skeletal relationship, small diameter or length of the screw, improper insertion torque, and placement in free mucosa or thin cortical bone. Nevertheless, most researchers unanimously stated that inflammation of soft tissues surrounding the microimplant is the predominant factor jeopardizing TISAD stability, which is fully confirmed by the most recent meta-analysis of the factors related to microimplant failures. The authors concluded that variables such as age, sex, and type of loading of the screw have some mild impact on the stability of the microimplant, whereas inflammation of soft tissues results in as high as a 9-fold increase of the risk of microimplant failure. This conclusion corresponds well with the results of experimental studies showing that the inflammatory process spreading from the soft tissues causes degeneration of the bone surrounding the implant, which then loses stability and needs replacement. Taking these phenomena into account, prevention of soft tissue inflammations seems to be a crucial measure for improvement of microimplant stability.

Infectious inflammation develops when oral bacteria penetrate the areas surrounding the TISAD; this is likely to happen at 2 times: (1) during and shortly after implantation, when tissue continuity is broken; and (2) during the whole period of microimplant loading, via the fissure between the microimplant head and the soft tissues. The reported microimplant survival analyses show that most failures take place within the first few weeks after TISAD insertion, indicating that factors acting during and immediately after implantation are crucial for stability: ie, host and operative factors. On the other hand, considering the long-term issues, the meta-analysis by Papageorgiou et al showed no influence of oral hygiene on the stability of microimplants; this significantly undermines the importance of long-term hygiene maintenance aspects. Thus, according to the evidence, operative-related factors and not maintenance ones should be screened for refinements to improve microscrew survival rates.

In general, development of infections in the surgical site depends on patient-host and surgery-related factors. Taking into account that most of a patient’s characteristics (age and bone quality) cannot be modified, prevention of infections should focus on the surgical aspects of the insertion procedure, which include (1) localization and preparation of the operative area; (2) invasiveness, technique, and duration of the procedure; and (3) use of antimicrobial agents. When performed properly, microimplantation is a quick and minimally invasive procedure leaving few possibilities for technical improvement. On the other hand, use of antimicrobial agents may exert a favorable effect on prevention of infections during microimplantation. The literature provides scarce data on the use of antimicrobials related to microimplants; a few authors have barely mentioned administration of antibiotics in their descriptions of the surgical protocol ( Table I ). Various regimens ranging from 1 dose before implantation up to 7 days postoperatively were applied, but no author provided any rationale supporting use of the antibiotics in conjunction with the microimplants. Therefore, up to now, no studies have directly investigated the impact of antibiotics on the stability of orthodontic microimplants. However, taking into account a similar model, a meta-analysis evaluating the influence of antibiotic prophylaxis on the survival of dental implants showed that a single dose of preoperative prophylaxis improved the success rates from 92% to 96%, which was statistically and clinically significant. Thus, the question arises whether a similar effect could be obtained for orthodontic microimplants. On the other hand, we must not forget that administration of antibiotics has some significant drawbacks: risk of adverse reactions and promotion of antibiotic-resistant species of bacteria that counterweigh the positive effects.