Distal radius fractures (DRFs) are common injuries that represent 17% of all adult upper extremity fractures. Some fractures deemed appropriate for nonsurgical management following closed reduction and casting exhibit delayed secondary displacement (greater than two weeks from injury) and require late surgical intervention. This can lead to delayed rehabilitation and functional outcomes. This study aimed to determine which demographic and radiographic features can be used to predict delayed fracture displacement.

This is a multicentre retrospective case-control study using radiographs extracted from our Analytics Data Integration, Measurement and Reporting (DIMR) database, using diagnostic and therapeutic codes. Skeletally mature patients aged 18 years of age or older with an isolated DRF treated with surgical intervention between two and four weeks from initial injury, with two or more follow-up visits prior to surgical intervention, were included. Exclusion criteria were patients with multiple injuries, surgical treatment with fewer than two clinical assessments prior to surgical treatment, or surgical treatment within two weeks of injury. The proportion of patients with delayed fracture displacement requiring surgical treatment will be reported as a percentage of all identified DRFs within the study period. A multivariable conditional logistic regression analysis was used to assess case-control comparisons, in order to determine the parameters that are mostly likely to predict delayed fracture displacement leading to surgical management. Intra- and inter-rater reliability for each radiographic parameter will also be calculated.

A total of 84 age- and sex-matched pairs were identified (n=168) over a 5-year period, with 87% being female and a mean age of 48.9 (SD=14.5) years. Variables assessed in the model included pre-reduction and post-reduction radial height, radial inclination, radial tilt, volar cortical displacement, injury classification, intra-articular step or gap, ulnar variance, radiocarpal alignment, and cast index, as well as the difference between pre- and post-reduction parameters. Decreased pre-reduction radial inclination (Odds Ratio [OR] = 0.54; Confidence Interval [CI] = 0.43 – 0.64) and increased pre-reduction volar cortical displacement (OR = 1.31; CI = 1.10 – 1.60) were significant predictors of delayed fracture displacement beyond a minimum of 2-week follow-up. Similarly, an increased difference between pre-reduction and immediate post reduction radial height (OR = 1.67; CI = 1.31 – 2.18) and ulnar variance (OR = 1.48; CI = 1.24 – 1.81) were also significant predictors of delayed fracture displacement.

Cast immobilization is not without risks and delayed surgical treatment can result in a prolong recovery. Therefore, if reliable and reproducible radiographic parameters can be identified that predict delayed fracture displacement, this information will aid in earlier identification of patients with DRFs at risk of late displacement. This could lead to earlier, appropriate surgical management, rehabilitation, and return to work and function.

Advances in orthopaedic surgery have led to minimally invasive techniques to decrease patient morbidity by minimizing surgical exposure, but also limits direct visualization. This has led to the increased use of intraoperative fluoroscopy for fracture management. Unfortunately, these procedures require the operating surgeon to stay in close proximity to the patient, thus being exposed to radiation scatter. The current National Council on Radiation Protection recommends no more than 50 mSv of radiation exposure to avoid ill-effects. Risks associated with radiation exposure include cataracts, skin, breast and thyroid cancer, and leukemia. Despite radiation protection measures, there is overwhelming evidence of radiation-related diseases in orthopaedic surgeons. The risk of developing cancer (e.g. thyroid carcinoma and breast cancer) is approximately eight times higher than in unexposed workers. Despite this knowledge, there is a paucity of evidence on radiation exposure in orthopaedic surgery residents, therefore the goal of this study is to quantify radiation exposure in orthopaedic surgery residents.

We hypothesize that orthopaedic surgery residents are exposed to a significant amount of radiation throughout their training. We specifically aim to: 1) quantify the amount of radiation exposure throughout a Canadian orthopaedic residency training program and 2) determine the variability in resident radiation exposure by rotation assignment and year of training.

This ongoing prospective cohort study includes all local orthopaedic surgery residents who meet eligibility criteria. Inclusion criteria: 1) adult residents in an orthopaedic surgery residency program. Exclusion criteria: 1) female residents who are pregnant, and 2) residents in a non-surgical year (i.e. leave of absence, research, Masters/PhD). After completion of informed consent, each eligible resident will wear a dosimeter to measure radiation exposure in a standardized fashion. Dosimeters will be worn on standardized lanyards underneath lead protection in their left chest pocket during all surgeries that require radiation protection. Control dosimeters will be worn on the outside of each resident's scrub cap for comparison. Dosimeter readings will then be reported on a monthly and rotational basis. All data will be collected on a pre-developed case report form. All data will be de-identified and stored on a secure electronic database (REDCap). In addition to monthly and rotational dosimeter readings, residents will also report sex, height, level of training, parental status, and age for secondary subgroup analyses. Residents will also report if they have personalized lead or other protective equipment, including lead glasses. Resident compliance with dosimeter use will be measured by self report of >80% use on operative days. Interim analysis will be performed at the 6-month time point and data collection will conclude at the 1 year time point.

Data collection began in July 2018 and interim 6-month results will be available for presentation at the CORA annual meeting in June 2019.

This is the first prospective study quantifying radiation exposure in Canadian orthopaedic residents and the results will provide valuable information for all Canadian orthopaedic training programs.

It is estimated that a quarter to half of all hospital waste is produced in the operating room. Recycling of surgical waste in the perioperative setting is largely underutilized, despite the fact that many of the materials being discarded can be potentially recycled safely and easily. Given this mounting waste production, recycling programs have become increasingly popular. Therefore, the primary objective of this study is assess the effect of these recent eco-friendly polices by determining the amount of waste and recycling produced in the pre-operative and operative time period for several orthopaedic subspecialties.

Surgical cases were prospectively chosen and assigned to an orthopaedic subspecialty category, which included trauma, arthroplasty, sports, foot and ankle, upper extremity, and paediatrics. The preoperative phase began with the opening of the surgical case carts and concluded with the end of skin preparation. The intraoperative period began after skin preparation was complete, and concluded after the operating room was cleaned. At the end of the preoperative period all surgical waste was weighed and divided into recyclables and non-recyclables. Following the intraoperative period, surgical waste was divided into recyclables, non-recyclables, linens, and biohazardous waste streams. All bags were weighed in a standardized fashion using a portable hand held scale. The primary outcome of interest was the amount of recyclable waste produced per case. Secondary outcomes included the amount of nonrecyclable, biohazardous and total waste produced during the same time intervals. Statistical analysis was then completed using (ANOVA) to detect differences between specialties.

This study included 55 procedures collected over a 1-month period at two hospitals from October 2017 to November 2017. A total of 341 kg of waste was collected with a mean mass of 6.2 kg per case. In terms of primary outcomes, arthroplasty surgery produced a significantly greater amount of recyclable waste per case in the preoperative (2327.9 g)and intraoperative (938.6 g)period. It also produced the greatest amount of total recyclable waste per case, resulting in a significantly greater ratio of waste recycling per case then nearly all other specialties in the preoperative (86.2%) and intraoperative period (14.5%). In terms of secondary outcomes, arthroplasty surgery similarly produced a significantly greater amount of nonrecyclable waste per case then all other specialties (5823.6 g), the majority of which was produced during the intraoperative period (5512.9 g). Arthroplasty surgery also produced a significantly greater amount of biohazardous waste then all other specialties (409.3 g). The majority of surgical waste was produced in the intraoperative period compared to the preoperative period. In the preoperative period an average of 74.4% of waste was recyclable, compared to 7.6% of waste produced during the intraoperative period. In total, the average amount of waste recycled per case was 25.6%. Biohazardous waste only constituted 1.8% of the total waste mass.

Orthopaedic surgery is a significant source of waste production in our hospital system. Among orthopaedic subspecialties, arthroplasty is one of the largest waste producers, but also has the highest potential for recycling of materials. Effective OR recycling programs can significantly reduce our ecological footprint by diverting waste from landfills. In particular, the preoperative period has significant potential for landfill diversion as our study showed that nearly three quarters of all waste in this period can be effectively recycled.