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201. Pan-Cancer Insights: A Study of Microbial Metabolite Receptors in Malignancy Dynamics.

Author

Dovrolis, Nikolas, Spathakis, Michail, Collins, Alexandra R., Pandey, Varun Kumar, Uddin, Muhammad Ikhtear, Anderson, Donald D., Kaminska, Tetiana, Paspaliaris, Vasilis, and Kolios, George

Abstract

Simple Summary: Research increasingly shows that bacteria, the largest part of the gut microbiome, may play a significant role in cancer. These microorganisms produce metabolites that can travel through the body and interact with host cells via microbial metabolite receptors, potentially affecting cancer development. This study investigates the involvement of these receptors in human cells across twenty-three types of cancer. By analyzing data from both cancer cell lines and human tumor samples, we examined how these interactions may impact key cancer-related processes, such as immune response, tumor growth, and spread. Notably, we identified several receptors that are consistently altered in cancer, which might serve as helpful biomarkers for diagnosis or treatment. This research highlights the potential of targeting the gut microbiome in cancer therapy and provides valuable insights for developing new cancer treatments based on microbiome interactions. Background/Objectives: The role of the gut microbiome in cancer biology has become an increasingly prominent area of research, particularly regarding the role of microbial metabolites and their receptors (MMRs). These metabolites, through the various gut–organ axes, have been proven to influence several pathogenetic mechanisms. This study conducted a comprehensive pan-cancer analysis of MMR transcriptomic profiles across twenty-three cancer types, exploring the mechanisms through which they can influence cancer development and progression. Methods: Utilizing both cancer cell lines from CCLE (Cancer Cell Line Encyclopedia) and human tumor samples from TCGA (The Cancer Gene Atlas), we analyzed 107 MMRs interacting with microbial metabolites such as short-chain fatty acids, bile acids, indole derivatives, and others while studying their interactions with key known cancer genes. Results: Our results revealed that certain MMRs, such as GPR84 and serotonin receptors, are consistently upregulated in various malignancies, while others, like ADRA1A, are frequently downregulated, suggesting diverse roles in cancer pathophysiology. Furthermore, we identified significant correlations between MMR expression and cancer hallmark genes and pathways, including immune evasion, proliferation, and metastasis. Conclusions: These findings suggest that the interactions between microbial metabolites and MMRs may serve as potential biomarkers for cancer diagnosis, prognosis, and therapy, highlighting their therapeutic potential. This study underscores the significance of the microbiota–cancer axis and provides novel insights into microbiome-based strategies for cancer treatment. [ABSTRACT FROM AUTHOR]

Published
2024
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204. Postulated an Airborne ECM Threat.

Author

ARMY ELECTRONICS COMMAND FORT MONMOUTH N J, Anderson,Donald D., ARMY ELECTRONICS COMMAND FORT MONMOUTH N J, and Anderson,Donald D.

Abstract

This report will permit the reader to postulate his own ECM threat based on US technology. He will be able to calculate the power of airborne jammers at any frequency from 0.2 to 12 GHz and make a state-of-the-art estimate or estimate future threats (1980). He will also know tube power, antenna gain, system losses, prime power requirements, and total system weight. The information in this report is based entirely on unclassified US information. (Author)

Published
1976

206. Influence of sidewall retention and interference fit in total ankle replacement on implant‐bone micromotion: A finite element study.

Author

Johnson, Joshua E., Clarke, Gabriel A., de Cesar Netto, Cesar, and Anderson, Donald D.

Subjects
*TOTAL ankle replacement, *FINITE element method, *INHOMOGENEOUS materials
Abstract

The success of uncemented total ankle replacement (TAR) is linked to initial stability because bony ingrowth depends upon limited early micromotion. Tibial implant design fixation features resist micromotion aided by bony sidewall retention and interference fit. Our goal was to investigate factors influencing implant‐bone micromotion in TAR. Two TAR tibial components were virtually inserted into CT‐derived computer models of two distal tibias from patients with end‐stage ankle arthritis. Density‐based inhomogeneous material assignment was used to model bone compaction during press‐fit. Finite element analysis (FEA) was used to simulate three fixation cases: (1) no sidewalls + line‐to‐line fit, (2) sidewalls + line‐to‐line fit, and (3) sidewalls + 50, 100, or 200 µm interference fit. Kinetic profiles from the stance phase of gait were simulated and micromotions computed from FEA output. Without sidewalls or interference fit, micromotions were largest in early and late stance, with largest micromotions (averaging ~150–250 µm) observed near heel strike. Micromotions decreased 39%–62% when sidewalls were retained. When interference fit was also modeled, micromotions decreased another 37%–61% to ~10 µm. Micromotion differences between patients persisted with sidewall retention but largely disappeared with interference fit. This study presents new insights into the effects of TAR fixation features on implant‐bone micromotion. Stability appeared to be influenced by surrounding bone quality, but this influence was greatly diminished when interference fit was introduced. More complete understanding of TAR implant features and performance is needed, but our results show the importance of bone quality and interference fit in the stability of uncemented TAR. [ABSTRACT FROM AUTHOR]

Published
2024
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207. Foot offloading associated with carbon fiber orthosis use: A pilot study.

Author

Anderson, Kirsten M., Corlett, Molly A., Magdziarz, Sara M., Anderson, Donald D., and Wilken, Jason M.

Subjects
*CARBON fibers, *LEG, *CHRONIC pain, *GAIT disorders, *MILITARY service
Abstract

Traumatic lower limb injuries can result in chronic pain. Orthotic interventions are a leading conservative approach to reduce pain, manage loading, and protect the foot. Robust carbon fiber custom dynamic orthoses (CDOs) designed for military service members have been shown to reduce foot loading. However, the effect of carbon fiber orthosis design, including designs widely used in the civilian sector, on foot loading is unknown. Determine if carbon fiber orthoses alter foot loading during gait. Loadsol insoles were used to measure peak forces and force impulse acting on the forefoot, midfoot, hindfoot, and total foot. Nine healthy, able-bodied individuals participated. Force impulse was quantified as cumulative loading throughout stance phase. Participants walked without an orthosis and with three carbon fiber orthoses of differing designs: a Firm stiffness CDO, a Moderate stiffness CDO, and a medial and lateral strut orthosis (MLSO). There were significant main effects of orthosis condition on peak forefoot forces as well as forefoot and hindfoot force impulse. Peak forefoot forces were significantly lower in the Moderate and Firm CDOs compared to no orthosis and MLSO. Compared to walking without an orthosis, forefoot force impulse was significantly lower and hindfoot force impulse was significantly greater in all carbon fiber orthoses. Additionally, hindfoot force impulse in the Firm CDO was significantly higher than in the MLSO and Moderate CDO. The three carbon fiber orthosis designs differed regarding foot loading, with more robust orthoses providing greater forefoot offloading. Orthosis-related changes in forefoot loading suggest that carbon fiber orthoses could reduce loading-associated pain during gait. However, increased hindfoot force impulse suggests caution should be used when considering carbon fiber orthoses for individuals at risk of skin breakdown with repetitive loading. • Compared to walking without an orthosis, peak forefoot forces decreased with carbon fiber custom dynamic orthosis use. • All carbon fiber orthoses significantly decreased forefoot force impulse compared to walking without an orthosis. • All carbon fiber orthoses significantly increased hindfoot force impulse compared to walking without an orthosis. [ABSTRACT FROM AUTHOR]

Published
2024
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208. The relationship of three‐dimensional joint space width on weight‐bearing CT with pain and physical function.

Author

Kothari, Mayank D., Rabe, Kaitlin G., Anderson, Donald D., Nevitt, Michael C., Lynch, John A., Franz, Hayden, and A. Segal, Neil

Subjects
*PAIN, *COMPUTED tomography, *OSTEOARTHRITIS, *KNEE, *SPACE
Abstract

Limitations of plain radiographs may contribute to poor sensitivity in the detection of knee osteoarthritis and poor correlation with pain and physical function. Three‐dimensional (3D) joint space width (JSW), measured from weight‐bearing computed tomography (CT) images, may yield a more accurate correlation with patients' symptoms. We assessed the cross‐sectional association between 3D JSW and self‐reported pain and physical function. Five hundred twenty eight knees (57% women) were analyzed from Multicenter Osteoarthritis Study participants. An upright weight‐bearing CT scanner was used to acquire bilateral, weight‐bearing, fixed‐flexion images of the knees. A 3D dataset was reconstructed from cone beam projections and JSW was calculated across the joint surface. The percentages of the apposed medial tibiofemoral joint surface with JSW less than 2.0 and 2.5 mm, respectively, were calculated. Pain and physical function were measured using Western Ontario and McMaster Universities Osteoarthritis Index. Participants who reported greater pain severity tended to have a greater joint area with JSW less than 2.0 mm (P =.07 for the highest vs the lowest tertile). Participants who reported greater functional limitations had a greater joint area with JSW less than 2.0 mm (P =.02 for the highest vs the lowest tertile). There appears to be an association between the medial tibiofemoral area with JSW less than 2.0 mm and pain and physical function. [ABSTRACT FROM AUTHOR]

Published
2020
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209. Virtual Pre-Operative Reconstruction Planning for Comminuted Articular Fractures.

Author

Thomas, Thaddeus P., Anderson, Donald D., Willis, Andrew R., Marsh, J. Lawrence, and Brown, Thomas D.

Subjects
ALGORITHMS, FRACTURE fixation, TIBIA injuries, EXTREMITIES (Anatomy), TREATMENT of fractures
Abstract

The article discusses a study of using an automated bone segmentation and three-dimensional (3D) puzzle solving algorithms to obtain fracture reconstructions in highly comminuted tibial plafond fractures. The study involved 10 tibial plafond fracture cases. Fragment native surfaces were matched to an intact template created from a mirror image of the healthy contralateral limb to reconstruct the tibia. The significance of virtual pre-operative reconstruction planning to articular fracture treatment is noted.

Published
2010

210. EQUIVALENCE OF ELASTIC CONTACT AND FINITE ELEMENT MODELS OF PATIENT-SPECIFIC CONTACT STRESS EXPOSURE IN THE HUMAN ANKLE.

Author

Kern, Andrew M., Anderson, Donald D., and Brown, Thomas D.

Subjects
ANKLE, JOINTS (Anatomy), CONTACT mechanics, BIOMECHANICS, FINITE element method
Abstract

The article discusses a study of the equivalence of contact stresses (CS) in the human ankle using elastic contact (EC) and finite element (FE) models. The researchers assessed CS in eleven models of intact ankles and compared the results with the FE results on site-by-site basis. They found a mean difference between EC and FE CS of 0.42 MegaPascals across all levels. They also observed that there was a small bias towards the EC having higher CS than FE.

Published
2010

222. Fluoroscopic image‐based behavior analysis can objectively explain subjective expert assessment of wire navigation skill.

Author

Mattioli, Dominik D., Thomas, Geb W., Long, Steven, Rölfing, Jan Duedal, and Anderson, Donald D.

Subjects
*BEHAVIORAL assessment, *OPERATING rooms, *NAVIGATION, *PROSODIC analysis (Linguistics), *IMAGE analysis
Abstract

Psychomotor skill and decision‐making efficiency in surgical wire navigation can be objectively evaluated by analysis of intraoperative fluoroscopic image sequences. Prior work suggests that such image‐based behavior analysis of operating room (OR) performance can predict performer experience level (R2 = 0.62) and agree with expert opinion (the current standard) on the quality of a final implant construct (R2 = 0.59). However, it is unclear how objective image‐based evaluation compares with expert assessments for entire technical OR performances. This study examines the relationships between three key variables: (1) objective image‐based criteria, (2) expert opinions, and (3) performing surgeon experience level. A paired‐comparison survey of seven experts, based upon eight OR fluoroscopic wire navigation image sequences, shows that the experts' preferences are best explained by objective metrics that reflect psychomotor and decision‐making behaviors which are counter‐productive to successful implant placement, like image count (R2 = 0.83) and behavior tally (R2 = 0.74). One such behavior, adjustments away from goal, uniquely correlated well with all three key variables: a fluoroscopic image‐based analysis composite score (R2 = 0.40), expert consensus (R2 = 0.76), and performer experience (R2 = 0.41). These results confirm that experts view less efficient technical behavior as indicative of lesser technical proficiency. While expert assessments of technical skill were reliable and consistent, neither individual nor consensus expert opinion appears to correlate with performer experience (R2 = 0.11). [ABSTRACT FROM AUTHOR]

Published
2024
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224. CHAIR MESSAGE.

Author

Redick, Thomas P. and Anderson, Donald D.

Published
2013

226. Computational techniques for the assessment of fracture repair.

Author

Anderson, Donald D, Thomas, Thaddeus P, Campos Marin, Ana, Elkins, Jacob M, Lack, William D, and Lacroix, Damien

Abstract

The combination of high-resolution three-dimensional medical imaging, increased computing power, and modern computational methods provide unprecedented capabilities for assessing the repair and healing of fractured bone. Fracture healing is a natural process that restores the mechanical integrity of bone and is greatly influenced by the prevailing mechanical environment. Mechanobiological theories have been proposed to provide greater insight into the relationships between mechanics (stress and strain) and biology. Computational approaches for modelling these relationships have evolved from simple tools to analyze fracture healing at a single point in time to current models that capture complex biological events such as angiogenesis, stochasticity in cellular activities, and cell-phenotype specific activities. The predictive capacity of these models has been established using corroborating physical experiments. For clinical application, mechanobiological models accounting for patient-to-patient variability hold the potential to predict fracture healing and thereby help clinicians to customize treatment. Advanced imaging tools permit patient-specific geometries to be used in such models. Refining the models to study the strain fields within a fracture gap and adapting the models for case-specific simulation may provide more accurate examination of the relationship between strain and fracture healing in actual patients. Medical imaging systems have significantly advanced the capability for less invasive visualization of injured musculoskeletal tissues, but all too often the consideration of these rich datasets has stopped at the level of subjective observation. Computational image analysis methods have not yet been applied to study fracture healing, but two comparable challenges which have been addressed in this general area are the evaluation of fracture severity and of fracture-associated soft tissue injury. CT-based methodologies developed to assess and quantify these factors are described and results presented to show the potential of these analysis methods. [ABSTRACT FROM AUTHOR]

Published
2014
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227. A Simulation Trainer for Complex Articular Fracture Surgery.

Author

Yehyawi, Tameem M., Thomas, Thaddeus P., Ohrt, Gary T., Marsh, J. Lawrence, Karam, Matthew D., Brown, Thomas D., and Anderson, Donald D.

Subjects
FRACTURE fixation, ARTICULAR cartilage, MEDICAL simulation, SURGERY
Abstract

An abstract of the article "A Simulation Trainer for Complex Articular Fracture Surgery," by Tameem M. Yehyawi and colleagues is presented.

Published
2013
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229. Influence of custom dynamic orthoses on tibiotalar joint reaction force and contact stress: A cadaveric study.

Author

Williamson, Lucinda, Brouillette, Marc, Miller, Tristan, Goetz, Jessica, Wilken, Jason, and Anderson, Donald D.

Subjects
*ANKLE joint, *REACTION forces, *PRESSURE sensors, *ACHILLES tendon, *CONTACT mechanics, *ANKLE
Abstract

Post-traumatic osteoarthritis (PTOA) often develops following tibial pilon fractures. Evidence suggesting PTOA development is driven by elevated articular contact stress from residual malreduction has led surgeons to strive for precise articular reduction, typically at the cost of extended operative time. Post-operative bracing using carbon fiber custom dynamic orthoses (CDOs) offers another means to decrease tibiotalar joint reaction force (JRF) and contact stress. The purpose of this cadaveric study was to measure how CDO stiffness influences ankle JRF and contact stress over the stance phase of gait. A servohydraulic load frame was used to test five cadaver ankles, with axial loading (240–330 N) and pneumatic actuation of the Achilles tendon (50–436 N) serving to quasi-statically model multiple points in the stance phase of gait. Three CDO rotational stiffness conditions were tested: (1) No CDO–0 Nm/deg, (2) low stiffness CDO–1.8 Nm/deg, and (3) moderate stiffness CDO–2.3 Nm/deg. JRF and contact stresses were measured using a piezoresistive pressure sensor inserted into the tibiotalar joint. An insole plantar pressure sensor placed between the cadaveric foot and CDO footplate measured limb/device interactions via the plantar center of pressure (COP). As limb loading progressed through stance, the plantar COP progressed from hindfoot to forefoot, as it would in normal gait. Both CDOs demonstrated decreases in JRF, reaching as high as 32% for the low CDO and 26% for the moderate CDO, with associated decreases in contact stress. This suggests that post-operative bracing could lessen PTOA risk after pilon fractures. [ABSTRACT FROM AUTHOR]

Published
2024
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230. Injury-related cell death and proteoglycan loss in articular cartilage: Numerical model combining necrosis, reactive oxygen species, and inflammatory cytokines.

Author

Kosonen, Joonas P., Eskelinen, Atte S. A., Orozco, Gustavo A., Nieminen, Petteri, Anderson, Donald D., Grodzinsky, Alan J., Korhonen, Rami K., and Tanska, Petri

Subjects
*ARTICULAR cartilage, *CELL death, *REACTIVE oxygen species, *JOINT pain, *CARTILAGE regeneration, *CARTILAGE cells, *NECROSIS, *CARTILAGE
Abstract

Osteoarthritis (OA) is a common musculoskeletal disease that leads to deterioration of articular cartilage, joint pain, and decreased quality of life. When OA develops after a joint injury, it is designated as post-traumatic OA (PTOA). The etiology of PTOA remains poorly understood, but it is known that proteoglycan (PG) loss, cell dysfunction, and cell death in cartilage are among the first signs of the disease. These processes, influenced by biomechanical and inflammatory stimuli, disturb the normal cell-regulated balance between tissue synthesis and degeneration. Previous computational mechanobiological models have not explicitly incorporated the cell-mediated degradation mechanisms triggered by an injury that eventually can lead to tissue-level compositional changes. Here, we developed a 2-D mechanobiological finite element model to predict necrosis, apoptosis following excessive production of reactive oxygen species (ROS), and inflammatory cytokine (interleukin-1)-driven apoptosis in cartilage explant. The resulting PG loss over 30 days was simulated. Biomechanically triggered PG degeneration, associated with cell necrosis, excessive ROS production, and cell apoptosis, was predicted to be localized near a lesion, while interleukin-1 diffusion-driven PG degeneration was manifested more globally. Interestingly, the model also showed proteolytic activity and PG biosynthesis closer to the levels of healthy tissue when pro-inflammatory cytokines were rapidly inhibited or cleared from the culture medium, leading to partial recovery of PG content. The numerical predictions of cell death and PG loss were supported by previous experimental findings. Furthermore, the simulated ROS and inflammation mechanisms had longer-lasting effects (over 3 days) on the PG content than localized necrosis. The mechanobiological model presented here may serve as a numerical tool for assessing early cartilage degeneration mechanisms and the efficacy of interventions to mitigate PTOA progression. Author summary: Osteoarthritis is one of the most common musculoskeletal diseases. When osteoarthritis develops after a joint injury, it is designated as post-traumatic osteoarthritis. A defining feature of osteoarthritis is degeneration of articular cartilage, which is partly driven by cartilage cells after joint injury, and further accelerated by inflammation. The degeneration triggered by these biomechanical and biochemical mechanisms is currently irreversible. Thus, early prevention/mitigation of disease progression is a key to avoiding PTOA. Prior computational models have been developed to provide insights into the complex mechanisms of cartilage degradation, but they rarely include cell-level cartilage degeneration mechanisms. Here, we present a novel approach to simulate how the early post-traumatic biomechanical and inflammatory effects on cartilage cells eventually influence tissue composition. Our model includes the key regulators of early post-traumatic osteoarthritis: chondral lesions, cell death, reactive oxygen species, and inflammatory cytokines. The model is supported by several experimental explant culture findings. Interestingly, we found that when post-injury inflammation is mitigated, cartilage composition can partially recover. We suggest that mechanobiological models including cell–tissue-level mechanisms can serve as future tools for evaluating high-risk lesions and developing new intervention strategies. [ABSTRACT FROM AUTHOR]

Published
2023
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231. The Inflamma-type: a patient phenotype characterized by a dysregulated inflammatory response after lower extremity articular fracture.

Author

Jacobs, Cale A., Olsen, Zachary M., Marchand, Lucas S., Kraus, Virginia B., Anderson, Donald D., and Haller, Justin

Subjects
*INFLAMMATION, *SYNOVIAL fluid, *ANKLE fractures, *CLUSTER analysis (Statistics), *TIBIAL plateau fractures, *MATRIX metalloproteinases, *OSTEOARTHRITIS
Abstract

Synovial fluid was collected from 113 patients who had suffered tibial plateau (n = 48), tibial plafond (n = 29), or rotational ankle fractures (n = 36). Concentrations of IL-1β, IL-1RA, IL-6, IL-8, IL-10, and MMP-1, -3, and -13 were quantified using multiplex assays. A cluster analysis of synovial fluid biomarker concentrations was performed. Patient demographics, fracture type, Injury Severity Score (ISS), Charlson Comorbidity Index (CCI), and biomarker concentrations were compared between clusters. A subset of patients demonstrated a dysregulated inflammatory response after articular fracture including elevated pro-inflammatory cytokines and degradative enzymes previously linked to the development of post-traumatic osteoarthritis. [ABSTRACT FROM AUTHOR]

Published
2023
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232. Surgical Skill Can be Objectively Measured From Fluoroscopic Images Using a Novel Image-based Decision Error Analysis (IDEA) Score.

Author

Long, Steven, Thomas, Geb W., Karam, Matthew D., Marsh, J. Lawrence, and Anderson, Donald D.

Subjects
*DECISION making, *OPERATING rooms, *OPERATIVE surgery, *FEMUR head, *ABILITY, *SURGICAL errors, *ORTHOPEDIC implants, *ORTHOPEDIC surgery, *HIP fractures, *FLUOROSCOPY, *INTERNSHIP programs, *CLINICAL competence, *RESEARCH funding, MEDICAL error statistics
Abstract

Background: To advance orthopaedic surgical skills training and assessment, more rigorous and objective performance measures are needed. In hip fracture repair, the tip-apex distance is a commonly used summative performance metric with clear clinical relevance, but it does not capture the skill exercised during the process of achieving the final implant position. This study introduces and evaluates a novel Image-based Decision Error Analysis (IDEA) score that better captures performance during fluoroscopically-assisted wire navigation.Questions/purposes: (1) Can wire navigation skill be objectively measured from a sequence of fluoroscopic images? (2) Are skill behaviors observed in a simulated environment also exhibited in the operating room? Additionally, we sought to define an objective skill metric that demonstrates improvement associated with accumulated surgical experience.Methods: Performance was evaluated both on a hip fracture wire navigation simulator and in the operating room during actual fracture surgery. After examining fluoroscopic image sequences from 176 consecutive simulator trials (performed by 58 first-year orthopaedic residents) and 21 consecutive surgical procedures (performed by 19 different orthopaedic residents and one attending orthopaedic surgeon), three main categories of erroneous skill behavior were identified: off-target wire adjustments, out-of-plane wire adjustments, and off-target drilling. Skill behaviors were measured by comparing wire adjustments made between consecutive images against the goal of targeting the apex of the femoral head as part of our new IDEA scoring methodology. Decision error metrics (frequency, magnitude) were correlated with other measures (image count and tip-apex distance) to characterize factors related to surgical performance on both the simulator and in the operating room. An IDEA composite score integrating decision errors (off-target wire adjustments, out-of-plane wire adjustments, and off-target drilling) and the final tip-apex distance to produce a single metric of overall performance was created and compared with the number of hip wire navigation cases previously completed (such as surgeon experience levels).Results: The IDEA methodology objectively analyzed 37,000 images from the simulator and 688 images from the operating room. The number of decision errors (7 ± 5 in the operating room and 4 ± 3 on the simulator) correlated with fluoroscopic image count (33 ± 14 in the operating room and 20 ± 11 on the simulator) in both the simulator and operating room environments (R2 = 0.76; p < 0.001 and R2 = 0.71; p < 0.001, respectively). Decision error counts did not correlate with the tip-apex distance (16 ± 4 mm in the operating room and 12 ± 5 mm on the simulator) for either the simulator or the operating room (R2 = 0.08; p = 0.15 and R2 = 0.03; p = 0.47, respectively), indicating that the tip-apex distance is independent of decision errors. The IDEA composite score correlated with surgical experience (R2 = 0.66; p < 0.001).Conclusion: The fluoroscopic images obtained in the course of placing a guide wire contain a rich amount of information related to surgical skill. This points the way to an objective measure of skill that also has potential as an educational tool for residents. Future studies should expand this analysis to the wide variety of procedures that rely on fluoroscopic images.Clinical Relevance: This study has shown how resident skill development can be objectively assessed from fluoroscopic image sequences. The IDEA scoring provides a basis for evaluating the competence of a resident. The score can be used to assess skill at key timepoints throughout residency, such as when rotating onto/off of a new surgical service and before performing certain procedures in the operating room, or as a tool for debriefing/providing feedback after a procedure is completed. [ABSTRACT FROM AUTHOR]

Published
2021
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233. Weight-Bearing CT Scan After Tibial Pilon Fracture Demonstrates Significant Early Joint-Space Narrowing.

Author

Willey, Michael C., Compton, Jocelyn T., Marsh, J. Lawrence, Kleweno, Conor P., Agel, Julie, Scott, Elizabeth J., Bui, Gabrielle, Davison, John, and Anderson, Donald D.

Subjects
*ANKLE, *TRAUMA centers, *INTER-observer reliability, *COMPUTED tomography, *DISEASE progression, *STATISTICAL correlation
Abstract

Background: Posttraumatic osteoarthritis (PTOA) is a common and early sequela of tibial pilon fractures resulting in substantial long-term disability. New approaches are needed to objectively and reliably quantify early disease progression in order to critically assess the impact of interventions aimed at preventing or mitigating PTOA. Weight-bearing computed tomography (WBCT) scans provide a means for measuring joint space while the ankle is in a loaded, functional position. We assessed the interrater and intrarater reliability of a standardized, regional method to quantify joint-space loss following tibial pilon fracture compared with the uninjured contralateral ankle.Methods: We prospectively enrolled 20 patients with intra-articular tibial pilon fractures that were surgically treated at 1 of 2 level-I trauma centers. Six months after injury, bilateral ankle WBCT scans were obtained. Joint space was measured by 4 reviewers at 9 discrete regions of the tibiotalar articulation on sagittal images. Measurements were repeated by reviewers 2 weeks later. To characterize the measurement method, interrater correlation coefficient estimates and test-retest reproducibility were calculated.Results: The mean tibiotalar joint space was 21% less in the injured ankles compared with the contralateral uninjured ankles (p < 0.0001). The middle-lateral and middle-central regions of the joint demonstrated the greatest decrease in joint space between injured and uninured ankles. The interrater correlation coefficient of the measurement technique was 0.88, and the test-retest reproducibility was 0.80, indicating good reliability and reproducibility of the method.Conclusions: We developed a simple, standardized, and reliable technique to quantify tibiotalar joint space following tibial pilon fracture on WBCT. Significant loss of joint space is seen 6 months after the injury. This tool can be used to longitudinally quantify loss of joint space following pilon fracture and assess the impact of interventions to reduce PTOA. [ABSTRACT FROM AUTHOR]

Published
2020
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234. Do Skills Acquired from Training with a Wire Navigation Simulator Transfer to a Mock Operating Room Environment?

Author

Long, Steven A., Thomas, Geb, Karam, Matthew D., and Anderson, Donald D.

Subjects
*OPERATING rooms, *SURGICAL education, *WIRE, *TRAINING of surgeons, *TRANSFER of training, *SYNTHETIC training devices, *TASK performance
Abstract

Background: Skills training and simulation play an increasingly important role in orthopaedic surgical education. The intent of simulation is to improve performance in the operating room (OR), a trait known as transfer validity. No prior studies have explored how simulator-based wire navigation training can transfer to higher-level tasks. Additionally, there is a lack of knowledge on the format in which wire navigation training should be deployed.Questions/purposes: (1) Which training methods (didactic content, deliberate practice, or proficiency-based practice) lead to the greatest improvement in performing a wire navigation task? (2) Does a resident's performance using a wire navigation simulator correlate with his or her performance on a higher-level simulation task in a mock OR involving a C-arm, a radiopaque femur model, and a large soft tissue surrogate surrounding the femur?Methods: Fifty-five residents from four different medical centers participated in this study over the course of 2 years. The residents were divided into three groups: traditional training (included first-year residents from the University of Iowa, University of Minnesota, and the Mayo Clinic), deliberate practice (included first-year residents from the University of Nebraska and the University of Minnesota), and proficiency training (included first-year residents from the University of Minnesota and the Mayo Clinic). Residents in each group received a didactic introduction covering the task of placing a wire to treat an intertrochanteric fracture, and this was considered traditional training. Deliberate practice involved training on a radiation-free simulator that provided specific feedback throughout the practice sessions. Proficiency training used the same simulator to train on specific components of wire navigation, like finding the correct starting point, to proficiency before moving to assessment. The wire navigation simulator uses a camera system to track the wire and provide computer-generated fluoroscopy. After training, task performance was assessed in a mock OR. Residents from each group were assessed in the mock OR based on their use of fluoroscopy, total time, and tip-apex distance. Correlation analysis was performed to examine the relationship between resident performance on the simulator and in the mock OR.Results: Residents in the two simulation-based training groups had a lower tip-apex distance than those in the traditional training group (didactic training tip-apex distance: 24 ± 7 mm, 95% CI, 20-27; deliberate practice tip-apex distance: 16 ± 5 mm, 95% CI, 13-19, p = 0.001; proficiency training tip-apex distance: 15 ± 4 mm, 95% CI, 13-18, p < 0.001). Residents in the proficiency training group used more images than those in the other groups (didactic training: 22 ± 12 images, p = 0.041; deliberate practice: 19 ± 8 images; p = 0.012, proficiency training: 31 ± 14 images). In the two simulation-based training groups, resident performance on the simulator, that is, tip-apex distance, image use, and overall time, was correlated with performance in the mock OR (r-square = 0.15 [p = 0.030], 0.61 [p < 0.001], and 0.43 [p < 0.001], respectively).Conclusions: As residency programs are designing their curriculum to train wire navigation skills, emphasis should be placed on providing an environment that allows for deliberate practice with immediate feedback about their performance. Simulators such as the one presented in this study offer a safe environment for residents to learn this key skill.Level Of Evidence: Level II, therapeutic study. [ABSTRACT FROM AUTHOR]

Published
2019
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235. Discrete element analysis is a valid method for computing joint contact stress in the hip before and after acetabular fracture.

Author

Townsend, Kevin C., Thomas-Aitken, Holly D., Rudert, M. James, Kern, Andrew M., Willey, Michael C., Anderson, Donald D., and Goetz, Jessica E.

Subjects
*PHYSIOLOGICAL stress, *ACETABULUM (Anatomy), *DISCRETE element method, *PHYSICAL measurements, *DEAD loads (Mechanics), *COMPUTATIONAL biology, *WOUNDS & injuries
Abstract

Evaluation of abnormalities in joint contact stress that develop after inaccurate reduction of an acetabular fracture may provide a potential means for predicting the risk of developing post-traumatic osteoarthritis. Discrete element analysis (DEA) is a computational technique for calculating intra-articular contact stress distributions in a fraction of the time required to obtain the same information using the more commonly employed finite element analysis technique. The goal of this work was to validate the accuracy of DEA-computed contact stress against physical measurements of contact stress made in cadaveric hips using Tekscan sensors. Four static loading tests in a variety of poses from heel-strike to toe-off were performed in two different cadaveric hip specimens with the acetabulum intact and again with an intentionally malreduced posterior wall acetabular fracture. DEA-computed contact stress was compared on a point-by-point basis to stress measured from the physical experiments. There was good agreement between computed and measured contact stress over the entire contact area (correlation coefficients ranged from 0.88 to 0.99). DEA-computed peak contact stress was within an average of 0.5 MPa (range 0.2–0.8 MPa) of the Tekscan peak stress for intact hips, and within an average of 0.6 MPa (range 0–1.6 MPa) for fractured cases. DEA-computed contact areas were within an average of 33% of the Tekscan-measured areas (range: 1.4–60%). These results indicate that the DEA methodology is a valid method for accurately estimating contact stress in both intact and fractured hips. [ABSTRACT FROM AUTHOR]

Published
2018
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236. Mathematics as a conduit for translational research in post-traumatic osteoarthritis.

Author

Ayati, Bruce P., Kapitanov, Georgi I., Coleman, Mitchell C., Anderson, Donald D., and Martin, James A.

Subjects
*OSTEOARTHRITIS, *BIOMECHANICS, *ARTICULAR cartilage, *ARTICULAR ligament injuries, *TISSUE wounds, *MATHEMATICAL models, *TRANSPLANTATION of organs, tissues, etc.
Abstract

ABSTRACT Biomathematical models offer a powerful method of clarifying complex temporal interactions and the relationships among multiple variables in a system. We present a coupled in silico biomathematical model of articular cartilage degeneration in response to impact and/or aberrant loading such as would be associated with injury to an articular joint. The model incorporates fundamental biological and mechanical information obtained from explant and small animal studies to predict post-traumatic osteoarthritis (PTOA) progression, with an eye toward eventual application in human patients. In this sense, we refer to the mathematics as a 'conduit of translation.' The new in silico framework presented in this paper involves a biomathematical model for the cellular and biochemical response to strains computed using finite element analysis. The model predicts qualitative responses presently, utilizing system parameter values largely taken from the literature. To contribute to accurate predictions, models need to be accurately parameterized with values that are based on solid science. We discuss a parameter identification protocol that will enable us to make increasingly accurate predictions of PTOA progression using additional data from smaller scale explant and small animal assays as they become available. By distilling the data from the explant and animal assays into parameters for biomathematical models, mathematics can translate experimental data to clinically relevant knowledge. © 2016 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 35:566-572, 2017. [ABSTRACT FROM AUTHOR]

Published
2017
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237. Fractures of the tibial plateau involve similar energies as the tibial pilon but greater articular surface involvement.

Author

Dibbern, Kevin, Kempton, Laurence B., Higgins, Thomas F., Morshed, Saam, McKinley, Todd O., Marsh, J. Lawrence, and Anderson, Donald D.

Subjects
*TIBIAL plateau fractures, *OSTEOARTHRITIS, *BONE injuries, *COMPUTED tomography, *JOINT cracking (Human body)
Abstract

ABSTRACT Patients with tibial pilon fractures have a higher incidence of post-traumatic osteoarthritis than those with fractures of the tibial plateau. This may indicate that pilon fractures present a greater mechanical insult to the joint than do plateau fractures. We tested the hypothesis that fracture energy and articular fracture edge length, two independent indicators of severity, are higher in pilon than plateau fractures. We also evaluated whether clinical fracture classification systems accurately reflect severity. Seventy-five tibial plateau fractures and 52 tibial pilon fractures from a multi-institutional study were selected to span the spectrum of severity. Fracture severity measures were calculated using objective CT-based image analysis methods. The ranges of fracture energies measured for tibial plateau and pilon fractures were 3.2-33.2 Joules (J) and 3.6-32.2 J, respectively, and articular fracture edge lengths were 68.0-493.0 mm and 56.1-288.6 mm, respectively. There were no differences in the fracture energies between the two fracture types, but plateau fractures had greater articular fracture edge lengths ( p < 0.001). The clinical fracture classifications generally reflected severity, but there was substantial overlap of fracture severity measures between different classes. Similar fracture energies with different degrees of articular surface involvement suggest a possible explanation for dissimilar rates of post-traumatic osteoarthritis for fractures of the tibial plateau compared to the tibial pilon. The substantial overlap of severity measures between different fracture classes may well have confounded prior clinical studies relying on fracture classification as a surrogate for severity. © 2016 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 35:618-624, 2017. [ABSTRACT FROM AUTHOR]

Published
2017
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238. Three-Dimensional Coverage Maps in the Assessment of Chopart Subluxation in Progressive Collapsing Foot Deformity

Author

Cesar de Cesar Netto, Andrew Behrens, Matthieu Lalevee, Amanda Ehret, Nacime S. Mansur, Donald D. Anderson, John E. Femino, Francois Lintz, Alessio Bernasconi, Netto, Cesar de Cesar, Behrens, Andrew, Lalevee, Matthieu, Ehret, Amanda, Mansur, Nacime S., Anderson, Donald D., Femino, John E., Lintz, Francoi, and Bernasconi, Alessio

Subjects
Orthopedic surgery, Article, RD701-811
Abstract

Category: Basic Sciences/Biologics; Hindfoot; Midfoot/Forefoot Introduction/Purpose: Progressive collapsing foot deformity (PCFD), formerly termed Adult-Acquired Flatfoot Deformity (AAFD), is a complex 3D deformity characterized by peritalar subluxation (PTS) of the hindfoot through the triple joint complex. In this context, adjacent structures may adopt different positions and boney relations can change, producing areas increased contact or subluxation. The objective of this study was to use 3D distance maps (DMs) and coverage maps (CMs) from weightbearing CT (WBCT) images to assess subluxation across the Chopart joint in PCFD patients. We hypothesized that CMs would show decreased coverage indicative of subluxation through certain regions of the Chopart joint in PCFD patients when compared to the controls. Methods: In this IRB-approved, retrospective case-control study, we analyzed WBCT data of 18 consecutive patients with flexible PCFD and 10 controls. Using principle component analysis, candidate coverage area was divided into nine regions on the talar head and 4 regions on the calcaneal-cuboid (CC) articular surface. Novel 3D distance mapping (DM) technique was used to objectively characterize joint coverage across the entire Chopart joint surface on both the talus and calcaneus. Distance maps were measured in millimeters and colored to highlight covered areas. Areas with distances less than 4mm were defined to be covered, while areas with distances greater than 4mm were considered to be uncovered. Joint coverage was defined as percentage of articular area with DMs lower than 4 mm. Coverage Maps (CM) were created to highlight areas of coverage (teal) versus non- coverage (pink). Comparisons were performed with independent t-tests, assuming unequal variances. P values Results: Changes in coverage percentages of PCFD cases relative to controls are indicated in attached figure 1 . The middle lateral region of the talar head was found to have a 9% increase in coverage in PCFD cases relative to the controls (p = 0.011). The plantar region of the calcaneal-cuboid joint was found to have a 18% decrease in coverage compared to the controls. Except for the dorsal medial regions, the medial side of the talar head saw overall decreases in coverage. However, these values were not statistically significant. On the calcaneus, the plantar region of the calcaneal-cuboid joint was found to have a significant coverage decrease of 18% relative to the controls (p = 0.017). There was also a decrease in coverage observed in the medial region of the calcaneal-cuboid joint and an increase in the dorsal and lateral areas. Conclusion: Our results support the occurrence of significant Chopart joint changes in early flexible PCFD. Increased lateral and decreased medial/plantar talar head coverage point to internal rotation and plantarflexion of the talus. Associated dorsal migration of the cuboid where plantar and medial areas have decreased coverage indicate subluxation through the entirety of the Chopart joint. Novel 3D coverage mapping enabled objective quantification of subluxation though the Chopart joint in early stage PCFD. These findings may assist clinical decision making regarding the restoration of normal joint alignment during PCFD corrections. Further studies are needed to establish thresholds of change associated with degeneration.

Published
2022

239. Objective Structured Assessments of Technical Skills (OSATS) Does Not Assess the Quality of the Surgical Result Effectively.

Author

Anderson, Donald, Long, Steven, Thomas, Geb, Putnam, Matthew, Bechtold, Joan, Karam, Matthew, Anderson, Donald D, Thomas, Geb W, Putnam, Matthew D, Bechtold, Joan E, and Karam, Matthew D

Subjects
*PERFORMANCE evaluation, *ORTHOPEDICS, *FRACTURE fixation, *ORTHOPEDISTS, *ORTHOPEDIC surgery, *URETHANE foam, *TRAINING, *PHYSIOLOGY, *JOINT surgery, *JOINT injuries, *EDUCATIONAL test & measurement standards, *MEDICAL education standards, *CLINICAL competence, *CLINICAL medicine, *COMPARATIVE studies, *DEAD, *CURRICULUM, *EDUCATIONAL tests & measurements, *FLUOROSCOPY, *HUMAN anatomical models, *INTERNSHIP programs, *RESEARCH methodology, *MEDICAL cooperation, *MEDICAL education, *MEDICAL specialties & specialists, *INTERVENTIONAL radiology, *RESEARCH, *RESEARCH funding, *TASK performance, *TEACHING, *EVALUATION research, *KEY performance indicators (Management), *STANDARDS, RESEARCH evaluation
Abstract

Background: Performance assessment in skills training is ideally based on objective, reliable, and clinically relevant indicators of success. The Objective Structured Assessment of Technical Skill (OSATS) is a reliable and valid tool that has been increasingly used in orthopaedic skills training. It uses a global rating approach to structure expert evaluation of technical skills with the experts working from a list of operative competencies that are each rated on a 5-point Likert scale anchored by behavioral descriptors. Given the observational nature of its scoring, the OSATS might not effectively assess the quality of surgical results.Questions/purposes: (1) Does OSATS scoring in an intraarticular fracture reduction training exercise correlate with the quality of the reduction? (2) Does OSATS scoring in a cadaveric extraarticular fracture fixation exercise correlate with the mechanical integrity of the fixation?Methods: Orthopaedic residents at the University of Iowa (six postgraduate year [PGY]-1s) and at the University of Minnesota (seven PGY-1s and eight PGY-2s) undertook a skills training exercise that involved reducing a simulated intraarticular fracture under fluoroscopic guidance. Iowa residents participated three times during 1 month, and Minnesota residents participated twice with 1 month between their two sessions. A fellowship-trained orthopaedic traumatologist rated each performance using a modified OSATS scoring scheme. The quality of the articular reduction obtained was then directly measured. Regression analysis was performed between OSATS scores and two metrics of articular reduction quality: articular surface deviation and estimated contact stress. Another skills training exercise involved fixing a simulated distal radius fracture in a cadaveric specimen. Thirty residents, distributed across four PGY classes (PGY-2 and PGY-3, n = 8 each; PGY-4 and PGY-5, n = 7 each), simultaneously completed the exercise at individual stations. One of three faculty hand surgeons independently scored each performance using a validated OSATS scoring system. The mechanical integrity of each fixation construct was then assessed in a materials testing machine. Regression analysis was performed between OSATS scores and two metrics of fixation integrity: stiffness and failure load.Results: In the intraarticular fracture model, OSATS scores did not correlate with articular reduction quality (maximum surface deviations: R = 0.17, p = 0.25; maximum contact stress: R = 0.22, p = 0.13). Similarly in the cadaveric extraarticular fracture model, OSATS scores did not correlate with the integrity of the mechanical fixation (stiffness: R = 0.10, p = 0.60; failure load: R = 0.30, p = 0.10).Conclusions: OSATS scoring methods do not effectively assess the quality of the surgical result. Efforts must be made to incorporate assessment metrics that reflect the quality of the surgical result.Clinical Relevance: New objective, reliable, and clinically relevant measures of the quality of the surgical result obtained by a trainee are urgently needed. For intraarticular fracture reduction and extraarticular fracture fixation, direct physical measurement of reduction quality and of mechanical integrity of fixation, respectively, meet this need. [ABSTRACT FROM AUTHOR]

Published
2016
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241. Influence of Tibial Component Design Features and Interference Fit on Implant-Bone Micromotion in Total Ankle Replacement: A Finite Element Study.

Author

Clarke G, Johnson JE, de Cesar Netto C, and Anderson DD

Subjects
Humans, Joint Prosthesis, Ankle Joint surgery, Ankle Joint physiopathology, Biomechanical Phenomena, Arthroplasty, Replacement, Ankle methods, Finite Element Analysis, Prosthesis Design, Tibia surgery
Abstract

Background: Implant survivorship in uncemented total ankle replacement (TAR) is dependent on achieving initial stability. This is because early micromotion between the implant and bone can disrupt the process of osseointegration, leading to poor long-term outcomes. Tibial implant fixation features are designed to resist micromotion, aided by bony sidewall retention and interference fit. The goal of this study was to investigate design-specific factors influencing implant-bone micromotion in TAR tibial components with interference fit., Methods: Three implant designs with fixation features representative of current TAR tibial components (ARC, SPIKES, KEEL) were virtually inserted into models of the distal tibias of 2 patients with end-stage ankle arthritis. Tibia models were generated from deidentified patient computed tomography scans, with material properties for modeling bone behavior and compaction during press-fit. Finite element analysis (FEA) was used to simulate 2 fixation configurations: (1) no sidewalls or interference fit, and (2) sidewalls with interference fit. Load profiles representing the stance phase of gait were applied to the models, and implant-bone micromotions were computed from FEA output., Results: Sidewalls and interference fit substantially influenced implant-bone micromotions across all designs studied. When sidewalls and interference fit were modeled, average micromotions were less than 11 µm, consistent across the stance phase of gait. Without sidewalls or interference fit, micromotions were largest near either heel strike or toe-off. In the absence of sidewalls and interference fit, the amount of micromotion generally aligned inversely with the size of implant fixation features; the ARC design had the largest micromotion (~540 µm average), whereas the KEEL design had the smallest micromotion (~15 µm)., Conclusion: This study presents new insights into the effect of TAR fixation features on implant-bone micromotion. With sidewalls and interference fit, micromotion is predicted to be minimal for implants, whereas with no sidewalls and no interference fit, micromotion depended primarily on the implant design., Clinical Relevance: This study presents new insights into the effect of TAR primary fixation features on implant-bone micromotion. Although design features heavily influenced implant stability in the model, their influence was greatly diminished when interference fit was introduced. The results of this study show the relative importance of design features and interference fit in the predicted initial stability of uncemented TAR, potentially a key factor in implant survivorship., Competing Interests: Declaration of Conflicting InterestsThe author(s) declared no potential conflicts of interest with respect to the research, authorship, and/or publication of this article. Disclosure forms for all authors are available online.

Published
2024
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242. Ankle osteoarthritis: Toward new understanding and opportunities for prevention and intervention.

Author

Anderson DD, Ledoux WR, Lenz AL, Wilken J, Easley ME, and de Cesar Netto C

Subjects
Humans, Ankle Injuries prevention & control, Ankle Injuries therapy, Osteoarthritis prevention & control, Osteoarthritis therapy, Osteoarthritis etiology, Ankle Joint physiopathology
Abstract

The ankle infrequently develops primary osteoarthritis (OA), especially when compared to the hip and the knee. Ankle OA instead generally develops only after trauma. The consequences of end-stage ankle OA can nonetheless be extremely debilitating, with impairment comparable to that of end-stage kidney disease or congestive heart failure. Disconcertingly, evidence suggests that ankle OA can develop more often than is generally appreciated after even low-energy rotational ankle fractures and chronic instability associated with recurrent ankle sprains, albeit at a slower rate than after more severe trauma. The mechanisms whereby ankle OA develops after trauma are poorly understood, but mechanical factors are implicated. A better understanding of the prevalence and mechanical etiology of post-traumatic ankle OA can lead to better prevention and mitigation. New surgical and conservative interventions, including improved ligamentous repair strategies and custom carbon fiber bracing, hold promise for advancing treatment that may prevent residual ankle instability and the development of ankle OA. Studies are needed to fill in key knowledge gaps here related to etiology so that the interventions can target key factors. New technologies, including weight bearing CT and biplane fluoroscopy, offer fresh opportunities to better understand the relationships between trauma, ankle alignment, residual ankle instability, OA development, and foot/ankle function. This paper begins by reviewing the epidemiology of post-traumatic ankle OA, presents evidence suggesting that new treatment options might be successful at preventing ankle OA, and then highlights recent technical advances in understanding of the origins of ankle OA to identify directions for future research., (© 2024 The Author(s). Journal of Orthopaedic Research® published by Wiley Periodicals LLC on behalf of Orthopaedic Research Society.)

Published
2024
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243. A generalized objective CT-based method for quantifying articular fracture severity.

Author

Dibbern KN, Kern AM, and Anderson DD

Abstract

A CT-based method for objectively assessing fracture severity was previously developed and validated to address poor reliability in existing subjective fracture classification systems. The method involved quantifying the energy involved in creating a fracture. However, clinical utility of the method was hindered by reliance upon an intact contralateral CT and lengthy analysis time (8-10 h). Significant methodological improvements detailed here enable the assessment of fracture severity in any joints and bones, while obviating the need for an intact contralateral CT scan. Analysis time was reduced to <2 h per case. Fracture energies computed using the new methods showed strong agreement (R 2  = 0.95, p < 0.001) with prior results in analyzing twenty tibial pilon fractures. New metrics, articular fracture edge length and subchondral energy, were developed to better describe joint injuries by incorporating knowledge of preferential chondrocyte death along fracture edges. Based on two-year radiographic grading for these pilon fractures, fracture energy, articular fracture edge length, and subchondral energy were all significantly different (p < 0.01) between cases that did or did not develop post-traumatic osteoarthritis. These developments enable measurement of fracture severity in larger populations and in more clinically relevant timeframes with articular fractures involving a variety of joints and bones. This generalized assessment method offers opportunity to change the way severity is considered in fracture treatment algorithms. Studies involving larger cohorts are anticipated to yield insights into the impact of fracture severity on PTOA risk and serve as a foundation for evaluating new treatment strategies., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024. Published by Elsevier Ltd.)

Published
2024
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244. Increased Deltoid and Acromial Stress with Glenoid Lateralization and Onlay Humeral Stem Constructs in Reverse Shoulder Arthroplasty.

Author

Patterson BM, Johnson JE, Bozoghlian M, and Anderson DD

Abstract

Background: Reverse shoulder arthroplasty (RSA) designs include multiple options for glenoid component lateralization, and humeral component lateralization and distalization (inlay/onlay constructs). The influence of combined glenoid lateralization, and humeral distalization on acromial and deltoid stresses is not well understood. The purpose of this study was to evaluate changes in deltoid and acromial stresses with variations in glenoid lateralization, and with inlay versus onlay humeral components in RSA., Methods: Finite element analysis was performed using a RSA system with both inlay and onlay configurations. Variations in total glenoid lateralization from 3 to 9 mm were evaluated. Deltoid and acromial stresses were determined following virtual implantation and with 50° of external rotation., Results: Increased glenoid lateralization resulted in greater stress of the deltoid and acromion. There was a modest increase in deltoid stress with glenoid lateralization alone (7% and 7.5% with progressive lateralization from 3 to 6 mm and 6 to 9 mm, respectively), but deltoid stress increased substantially with use of an onlay construct (60% at 9 mm of glenoid lateralization). Acromial stress correspondingly increased 37% with glenoid lateralization, and up to 117% with an onlay humeral construct., Discussion: Increased lateralization of the glenoid component resulted in increased levels of deltoid and acromial stress. For a given amount of glenoid lateralization, utilization of an inlay stem decreased acromial and deltoid stresses compared to onlay constructs. These data allow surgeons to better understand the interactions of glenoid and humeral lateralization and distalization in the setting of contemporary RSA systems.Level of Evidence: Basic Science Study: Computer Modeling., Competing Interests: The authors declared no potential conflicts of interest with respect to the research, authorship, and/or publication of this article., (© The Author(s) 2024.)

Published
2024
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245. Accuracy of Volumetric Bone Mineral Density Measurement in Weight Bearing, Cone Beam Computed Tomography.

Author

Waungana TH, Qiu K, Tse JJ, Anderson DD, Emery CA, Boyd SK, and Manske SL

Subjects
Humans, Female, Calibration, Middle Aged, Knee Joint diagnostic imaging, Knee Joint physiology, Reproducibility of Results, Cancellous Bone diagnostic imaging, Aged, Absorptiometry, Photon methods, Bone Density, Cone-Beam Computed Tomography methods, Phantoms, Imaging, Weight-Bearing
Abstract

Background: Weight bearing computed tomography (WBCT) utilizes cone beam CT technology to provide assessments of lower limb joint structures while they are functionally loaded. Grey-scale values indicative of X-ray attenuation that are output from cone beam CT are challenging to calibrate, and their use for bone mineral density (BMD) measurement remains debatable. To determine whether WBCT can be reliably used for cortical and trabecular BMD assessment, we sought to establish the accuracy of BMD measurements at the knee using modern WBCT by comparing them to measurements from conventional CT., Methods: A hydroxyapatite phantom with three inserts of varying densities was used to systematically quantify signal uniformity and BMD accuracy across the acquisition volume. We evaluated BMD in vivo (n = 5, female) using synchronous and asynchronous calibration techniques in WBCT and CT. To account for variation in attenuation along the height (z-axis) of acquisition volumes, we tested a height-dependent calibration approach for both WBCT and CT images., Results: Phantom BMD measurement error in WBCT was as high as 15.3% and consistently larger than CT (up to 5.6%). Phantom BMD measures made under synchronous conditions in WBCT improved measurement accuracy by up to 3% but introduced more variability in measured BMD. We found strong correlations (R = 0.96) as well as wide limits of agreement (-324 mgHA/cm 3 to 183 mgHA/cm 3 ) from Bland-Altman analysis between WBCT and CT measures in vivo that were not improved by height-dependent calibration., Conclusion: Whilst BMD accuracy from WBCT was found to be dependent on apparent density, accuracy was independent of the calibration technique (synchronous or asynchronous) and the location of the measurement site within the field of view. Overall, we found strong correlations between BMD measures from WBCT and CT and in vivo measures to be more accurate in trabecular bone regions. Importantly, WBCT can be used to distinguish between anatomically relevant differences in BMD, however future work is necessary to determine the repeatability and sensitivity of BMD measures in WBCT., (Copyright © 2024 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published
2024
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246. Distal femur fractures: basic science and international perspectives.

Author

Nauth A, Haller J, Augat P, Anderson DD, McKee MD, Shearer D, Jenkinson R, and Pape HC

Abstract

Distal femur fractures are challenging injuries to manage, and complication rates remain high. This article summarizes the international and basic science perspectives regarding distal femoral fractures that were presented at the 2022 Orthopaedic Trauma Association Annual Meeting. We review a number of critical concepts that can be considered to optimize the treatment of these difficult fractures. These include biomechanical considerations for distal femur fixation constructs, emerging treatments to prevent post-traumatic arthritis, both systemic and local biologic treatments to optimize nonunion management, the relative advantages and disadvantages of plate versus nail versus dual-implant constructs, and finally important factors which determine outcomes. A robust understanding of these principles can significantly improve success rates and minimize complications in the treatment of these challenging injuries., Competing Interests: The authors report no conflicts relevant to this manuscript. No funding was received for the preparation of this manuscript., (Copyright © 2024 The Authors. Published by Wolters Kluwer Health, Inc. on behalf of the Orthopaedic Trauma Association.)

Published
2024
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247. Research Toward Understanding the Benefits and Limitations of Orthotic Use To Improve Mobility and Balance for Individuals With Neuropathic Conditions.

Author

Chrea B, Anderson DD, Roach K, and Wilken J

Subjects
Humans, Charcot-Marie-Tooth Disease physiopathology, Foot Orthoses, Cerebral Palsy physiopathology, Orthotic Devices, Gait Disorders, Neurologic physiopathology, Gait Disorders, Neurologic rehabilitation, Gait physiology, Walking physiology, Postural Balance physiology
Abstract

Background: Walking is a vital activity often compromised in individuals with neuropathic conditions. Charcot-Marie-Tooth (CMT) disease and Cerebral Palsy (CP) are two common neurodevelopmental disabilities affecting gait, predisposing to the risk of falls. With guiding scientific evidence limited, there is a critical need to better understand how surgical correction affects mobility, balance confidence, and gait compared to ankle foot orthosis (AFO) bracing. A systematic approach will enable rigorous collaborative research to advance clinical care., Methods: Key elements of this vision include 1) prospective studies in select patient cohorts to systematically compare conservative vs. surgical management, 2) objective laboratory-based evaluation of patient mobility, balance, and gait using reliable methods, and 3) use of patient-centric outcome measures related to health and mobility., Results: Valid and reliable standardized tests of physical mobility and balance confidence have been described in the literature. They include 1) the four-square step test, a widely used test of balance and agility that predicts fall risk, 2) the self-selected walking velocity, a measure of general mobility able to detect function change with orthosis use, and 3) the activity specific balance confidence scale, a survey instrument that assesses an individual's level of balance confidence during activity. Additionally, motion capture and ground reaction force data can be used to evaluate whole-body motion and loading, with discriminative biomechanical measures including toe clearance during the swing phase of gait, plantarflexion at 50% of swing, peak ankle plantarflexor moment, and peak ankle push-off power., Conclusion: The tools needed to support evidence-based practice and inform clinical decision making in these challenging patient populations are all available. Research must now be conducted to better understand the potential benefits and limitations of AFO use in the context of mobility and balance during gait for individuals with neuropathic conditions, particularly relative to those offered by surgical correction., Clinical Relevance: Following this path of research will provide comparative baseline data on mobility, balance confidence, and gait that can be used to inform an objective criterion-based approach to AFO prescription and the impact of surgical intervention., Competing Interests: Disclosures: The authors report no potential conflicts of interest related to this study., (Copyright © The Iowa Orthopaedic Journal 2024.)

Published
2024

248. A Dedicated Simulator Training Curriculum Improves Resident Performance in Surgical Management of Pediatric Supracondylar Humerus Fractures.

Author

Thomas G, Long S, Kurtzhals T, Connor E, Anderson DD, Karam M, and Kowalski H

Abstract

Background: The primary goal of including simulation in residency training is to improve technical skills while working outside of the operating room. Such simulation-related skill improvements have seldom been measured in the operating room. This is largely because uncontrolled variables, such as injury severity, patient comorbidity, and anatomical variation, can bias evaluation of an operating surgeon's skill. In this study, performance during the wire navigation phase of pediatric supracondylar humerus fracture fixation was quantitatively compared between 2 groups of orthopaedic residents: a standard training group consisting of residents who participated in a single simulator session of wire navigation training and an expanded training group consisting of residents who participated in a dedicated multifaceted wire navigation simulation training curriculum., Methods: To evaluate performance in the operating room, the full sequence of fluoroscopic images collected during wire navigation was quantitatively analyzed. Objective performance metrics included number of fluoroscopic images acquired, duration from placement of the first wire to that of the final wire, and wire spread at the level of the fracture. These metrics were measured from 97 pediatric supracondylar humerus fracture pinning surgeries performed by 28 different orthopaedic residents., Results: No differences were observed between the groups for wire spread in the final fluoroscopic images ( t (94) = 0.75, p = 0.45), an important clinical objective of the surgery. Residents who received the expanded simulator training used significantly fewer fluoroscopic images (mean of 46 vs. 61 images, t (85) = 2.25, p < 0.03) and required less time from first to final wire placement (mean of 11.2 vs. 14.9 minutes, t (83) = 2.53, p = 0.013) than the standard training group. A post hoc review of Accreditation Council for Graduate Medical Education case logs for 24 cases from the standard training group and for 21 cases from the expanded training group indicated that, at the time of surgeries, residents who received expanded training had completed fewer comparable cases than residents in the standard training group (mean of 13 vs. 21, t (42) = 2.40 p = 0.02). Further regression analysis indicated that the expanded simulator training produced an effect comparable with that associated with completing 10.5 similar surgical case experiences., Conclusions: This study demonstrates that training on a wire navigation simulator can lead to improved performance in the operating room on a critical skill for all orthopaedic residents. By taking fewer images and less time while maintaining sufficient pin spread, simulator-trained residents were objectively measured to have improved performance in comparison with residents who had not participated in the pediatric elbow simulator curriculum., Clinical Relevance: As programs aim to provide safe and effective training for critical orthopaedic skills such as pinning a pediatric elbow, this study demonstrates a simulator curriculum that has demonstrated the transfer of skill from a learning environment to the operating room., Competing Interests: Disclosure: The Disclosure of Potential Conflicts of Interest forms are provided with the online version of the article (http://links.lww.com/JBJSOA/A546)., (Copyright © 2023 The Authors. Published by The Journal of Bone and Joint Surgery, Incorporated. All rights reserved.)

Published
2023
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249. Current Challenges in Chronic Ankle Instability: Review and Perspective.

Author

Lalevée M, Anderson DD, and Wilken JM

Subjects
Humans, Ankle, Ankle Joint, Chronic Disease, Ankle Injuries complications, Joint Instability etiology
Abstract

Chronic ankle instability (CAI) is common, disabling, and represents a significant socioeconomic burden. Current treatment options are not adequately efficacious. CAI is multifaceted, yet it is commonly addressed in terms of either mechanical instability or functional impairment. Both are inherently linked. Basic research must be conducted to foster reliable translational research encompassing both mechanical and functional aspects. A review was conducted to identify CAI risk factors for inclusion in future studies, and we offer here opinions and perspectives for future research., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published
2023
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250. Establishing Construct Validity of a Novel Simulator for Guide Wire Navigation in Antegrade Femoral Intramedullary Nailing.

Author

Rölfing JD, Salling LB, Long SA, Vogt B, Anderson DD, Thomas GW, and Jensen RD

Subjects
Humans, Analysis of Variance, Bone Screws, Curriculum, Fracture Fixation, Intramedullary, Hip Fractures
Abstract

Background: Antegrade femoral intramedullary nailing (IMN) is a common orthopedic procedure that residents are exposed to early in their training. A key component to this procedure is placing the initial guide wire with fluoroscopic guidance. A simulator was developed to train residents on this key skill, building off an existing simulation platform originally developed for wire navigation during a compression hip screw placement. The objective of this study was to assess the construct validity of the IMN simulator., Methods: Thirty orthopedic surgeons participated in the study: 12 had participated in fewer than 10 hip fracture or IMN related procedures and were categorized as novices; 18 were faculty, categorized as experts. Both cohorts were instructed on the goal of the task, placing a guide wire for an IM nail, and the ideal wire position reference that their wire placement would be graded against. Participants completed 2 assessments with the simulator. Performance was graded on the distance from the ideal starting point, distance from the ideal end point, wire trajectory, duration, fluoroscopy image count, and other elements of surgical decision making. A two-way ANOVA analysis was used to analyze the data looking at experience level and trial number., Results: The expert cohort performed significantly better than the novice cohort on all metrics but one (overuse of fluoroscopy). The expert cohort had a more accurate starting point and completed the task while using fewer images and less overall time., Conclusion: This initial study shows that the IMN application of a wire navigation simulator demonstrates good construct validity. With such a large cohort of expert participants, we can be confident that this study captures the performance of active surgeons today. Implementing a training curriculum on this simulator has the potential to increase the performance of the novice level residents prior to their operating on a vulnerable patient. Level of Evidence: III ., (Copyright © The Iowa Orthopaedic Journal 2023.)

Published
2023

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