A-mode ultrasound-based intra-femoral bone cement detection and 3D reconstruction in RTHR.

Due to the difficulty of determining the 3D boundary of the cement-bone interface in Revision Total Hip Replacement (RTHR), the removal of the distal intra-femoral bone cement can be a time-consuming and risky operation. Within the framework of computer- and robot-assisted cement removal, the principles and first results of an automatic detection and 3D surface reconstruction of the cement-bone boundary using A-mode ultrasound are described. Sound propagation time and attenuation of cement were determined considering different techniques for the preparation of bone cement, such as the use of a vacuum system (Optivac, Biomet). A laboratory setup using a rotating, standard 5-MHz transducer was developed. The prototype enables scanning of bisected cement-prepared femur samples in a 90 degrees rotation range along their rotation axis. For system evaluation ex vivo, the distal femur of a human cadaver was prepared with bone cement and drilled (Ø 10 mm) to simulate the prosthesis cavity in a first approximation. The sample was cut in half and CT scanned (0.24 mm resolution; 0.5 mm distance; 0.5 mm thickness), and 3D voxel models of the manually segmented bone cement were reconstructed, providing the ground truth. Afterwards, 90 degrees segments of each ex-vivo sample were scanned by the A-mode ultrasound system. To obtain better ultrasound penetration, we used coded signal excitation and pulse compression filtering. A-mode ultrasound signal detection, filtering and segmentation were accomplished fully automatically. Subsequently, 3D voxel models of each sample were calculated. Accuracy evaluation of the measured ultrasound data was performed by ICP matching of each ultrasound dataset ( approximately 8000 points) to the corresponding CT dataset and calculation of the residual median distance error between the corresponding datasets. Prior to each ICP matching, an initial pre-registration was calculated using prominent landmarks in the corresponding datasets. This method yielded a median distance error in the region of 0.25 mm for the cement-bone interface in both femur halves.

[Surface pretreatment for prolonged survival of cemented tibial prosthesis components: full- vs. surface-cementation technique]. / Oberflächenkonditionierung für eine verbesserte Uberlebenswahrscheinlichkeit von Knieprothesen: Komplett- vs. Oberflächenzementiertechnik der Tibiakomponente.

Aseptic loosening of tibial components due to degradation of the interface between bone cement and metallic tibial shaft component is still a persistent problem, particularly for surface-cemented tibial components. The surface cementation technique has important clinical meaning in case of revision and for avoidance of stress shielding. This study was done to prove crack formation in the bone cement near the metallic surface when this is not coated. We propose a newly developed coating process by SiOx-PVD layering to avoid crack formation. A biomechanical model for a vibration fatigue test was done to prove that crack formation can be significantly reduced in the case of coated surfaces. It was found that coated tibial components showed a highly significant reduction of cement cracking near the metal/bone cement interface (p < 0.01) and a significant reduction of gap formation in the metal-to-bone cement interface (p < 0.05). Coating dramatically reduces hydrolytic- and stress-related crack formation at the prosthesis metal/bone cement interface. This leads to a more homogenous load transfer into the cement mantle which should reduce the frequency of loosening in the metal/bone cement/bone interfaces. With surface coating of the tibial component it should become possible that surface-cemented TKAs reveal similar loosening rates as TKAs both surface- and stem-cemented. This would be an important clinical advantage since it is believed that surface cementing reduces metaphyseal bone loss in the case of revision and stress shielding for a better bone health.

Surface pretreatment for prolonged survival of cemented tibial prosthesis components: full- vs. surface-cementation technique.

BACKGROUND: One of few persisting problems of cemented total knee arthroplasty (TKA) is aseptic loosening of tibial component due to degradation of the interface between bone cement and metallic tibial shaft component, particularly for surface cemented tibial components. Surface cementation technique has important clinical meaning in case of revision and for avoidance of stress shielding. Degradation of the interface between bone cement and bone may be a secondary effect due to excessive crack formation in bone cement starting at the opposite metallic surface. METHODS: This study was done to prove crack formation in the bone cement near the metallic surface when this is not coated. We propose a newly developed coating process by PVD layering with SiOx to avoid that crack formation in the bone cement. A biomechanical model for vibration fatigue test was done to simulate the physiological and biomechanical conditions of the human knee joint and to prove excessive crack formation. RESULTS: It was found that coated tibial components showed a highly significant reduction of cement cracking near the interface metal/bone cement (p < 0.01) and a significant reduction of gap formation in the interface metal-to-bone cement (p < 0.05). CONCLUSION: Coating dramatically reduces hydrolytic- and stress-related crack formation at the prosthesis interface metal/bone cement. This leads to a more homogenous load transfer into the cement mantle which should reduce the frequency of loosening in the interfaces metal/bone cement/bone. With surface coating of the tibial component it should become possible that surface cemented TKAs reveal similar loosening rates as TKAs both surface and stem cemented. This would be an important clinical advantage since it is believed that surface cementing reduces metaphyseal bone loss in case of revision and stress shielding for better bone health.

Influence of postoperative epidural analgesia with bupivacaine on intestinal motility, transit time, and anastomotic healing.

Epidural application of bupivacaine has been suggested to have a sympatholytic effect on spinal reflex mechanisms that shortens postoperative paralysis and leads to an improved transit time. The influence on anastomitic healing remains controversial. Laparotomy was performed in eight dogs. A short segment of the distal colon was resected and five electrodes were fixed on the serosa to measure the myoelectric activity (e.g., Migrating Myoelectric Complex--MMC). After operation a peridural catheter was placed between L7 and the sacral crest. One milliliter of bupivacaine 0.25% for each 3 kg of body weight was injected every 4 hours. Barium pellets coated in wax were placed into the stomach to allow radiographic representation of transit time. After 5 days the colon anastomosis was resected to measure the bursting pressure. In the peridural analgesia group (PDA) we found one small bowel intussusception and one covered anastomotic leakage. Postoperative PDA led to early and severe myoelectric activity but did not influence the time until the first MMC occurred (44 +/- 0.8 h, PDA; 44.6 +/- 1.5 h,control). Neither the transit time to the colon (50.2 +/- 1.9h, PDA; 51.7 +/- 5.5 h, control) nor the anastomotic healing was influenced (bursting pressure: 176 +/- 21.1 mmHg, PDA; 152 +/- 27.7 mmHg, control). Postoperative epidural analgesia with bupivacaine shortens intestinal paralysis. Early myoelectric activity with a lack of propulsive activity can cause complications like small bowel intussusception. Hence early postoperative enteral nutrition after epidural analgesia is risky. Because the influence of epidural analgesia on propulsive motility remains unclear, it seems reasonable to recommend its limited use in colon surgery.