High-Definition Intravascular Ultrasound Versus Optical Frequency Domain Imaging for the Detection of Calcium Modification and Fracture in Heavily Calcified Coronary Lesion

Purpose While optical frequency domain imaging (OFDI) can delineate calcium modification and fracture, the capability of high-definition intravascular ultrasound (HD-IVUS) for detecting these remains unclear. This study evaluated the diagnostic accuracy of HD-IVUS for assessing calcium modification and fracture as compared to OFDI. Methods HD-IVUS and OFDI were used during orbital or rotational atherectomy procedures conducted for 21 heavily calcified coronary lesions in 19 patients. With OFDI assessment used as the gold standard, diagnostic accuracies of HD-IVUS for calcium modification and fracture were compared every 1 mm to the matched pre-stenting images (n=1,129). Calcium modification, as assessed by OFDI, was defined as polished and concave-shaped calcium. For HD-IVUS, calcium modification was defined as the presence of reverberation with concave-shaped calcium. In both assessments, the definition of calcium fracture was defined as a slit or complete break in the calcium plate. Results Calcified plaque was found in 86.4% of analyzed OFDI images. Calcium modification and fracture were detected in 20.6% and 11.0% of detected calcified plaques. Sensitivity, specificity, positive and negative predictive values of HD-IVUS detection for calcium modification and fracture were 54.4%, 97.8%, 86.7%, 89.1% and 86.0%, 94.5%, 58.2%, 96.8%, respectively. Discordance cases between both assessments demonstrated that heterogeneous calcium visualized by OFDI, separated calcium and guide wire artifact can be misdiagnosed. Conclusion Diagnostic accuracies of HD-IVUS for assessing calcium modification and fracture were modest as compared to OFDI. These results suggest that OFDI guidance is more feasible during treatment of heavily calcified coronary lesions versus HD-IVUS guidance.

Intravascular Lithotripsy for Calcium Modification in Chronic Total Occlusion Percutaneous Coronary Intervention

Intravascular lithotripsy (IVL) has been shown to be safe and effective for calcium modification in nonocclusive coronary artery disease (CAD), but there are only case reports of its use in calcified chronic total occlusions (CTO). We report data from an international multicenter registry of IVL use during CTO percutaneous coronary intervention (PCI) and provide provisional data regarding its efficacy and safety. During the study period, IVL was used in 55 of 1053 (5.2%) CTO PCI procedures. IVL was used within the occluded segment after successful CTO crossing in 53 procedures and during incomplete CTO crossing in 2 cases. The mean J-CTO score was 3.1. CTO PCI technical and procedural success was achieved in 53 (96%) and 51 (93%) cases. Six patients had a procedural complication, with 3 main vessel perforations (5%). Two had covered stent implantation, one required pericardiocentesis, and one was managed conservatively. All had combination therapy with another calcium modification device. Two patients had a procedural myocardial infarction (PMI) (4%), and two others had a major adverse cardiovascular event (MACE) (4%) at a median follow-up of 13 (4–21) months. IVL can effectively facilitate calcium modification during CTO PCI. More data are required to establish the efficacy and safety of IVL and other calcium modification devices when used extraplaque or in combination during CTO PCI.

Calcium Modification Techniques in Complex Percutaneous Coronary Intervention

Percutaneous coronary intervention is the most common mode of revascularization and is increasingly undertaken in high-risk subsets, including the elderly. The presence of coronary artery calcification is increasingly observed and significantly limits technical success. The mechanisms for this are multi-factorial, including increased arterial wall stiffness and impaired delivery of devices, leading to suboptimal stent delivery, deployment, and expansion which are harbingers for increased risk of in-stent restenosis and stent thrombosis. Although conventional balloon pretreatment techniques aim to mitigate this risk by modifying the lesion before stent placement, many lesions remain resistant to conventional strategies, due to the severity of calcification. There have been several substantial technological advancements in calcium modification methods in recent years, which have allowed improved procedural success with low periprocedural complication rates. This review will summarize the current adjunctive modification technologies that can be employed to improve technical outcomes in percutaneous coronary intervention in calcific disease and the evidence supporting these tools.

Codepositon of Dopamine/Calcium on Titanium to Enhancing Implant Integration

Calcium plays an important role in various stages of bone repair. Surface calcium modification is a common method to improve the biocompatibility of titanium implant. In this work, anovel facile codeposition dopamine/calcium on titanium alloy method for orthopedics applications was developed. SEM-EDS results showed calcium microspheres uniformly deposited on titanium surface with dopamine. Water contact angle showed the dopamine/calcium modification layer improved the bare titanium surface hydrophobic property. And the dopamine/calcium coating enhanced the cell proliferation by MTT test. The ALP gene expression also showed the dopamine/calcium coating may enhance the cell early differentiation. Such facile method has great potential in titanium applications.