RESUMO
Purpose: Patients with diabetes and critical limb threatening ischemia (CLTI) are at significantly higher risk of limb loss and death. Here we evaluate the outcomes of orbital atherectomy (OA) for treatment of CLTI in patients with and without diabetes. Methods: Retrospective analysis of the LIBERTY 360 study was performed to evaluate baseline demographics, and peri-procedural outcomes between patients with CLTI, and with and without diabetes. Hazard ratios (HRs) were determined with Cox regression to examine the impact of OA in patients with diabetes and CLTI over a 3-year follow-up. Results: A total of 289 patients (201 with diabetes, 88 without diabetes) with Rutherford classification 4-6 were included. Patients with diabetes had higher proportion of renal disease (48.3% vs 28.4%, p=0.002), prior minor/major limb amputation (26% vs 8%, p<0.005), and presence of wounds (63.2% vs 48.9%, p=0.027). Operative times, radiation dosage, and contrast volume were similar between groups. The rate of distal embolization was higher in patients with diabetes (7.8% vs 1.9%, p=0.01; OR 4.33 [0.99, 18.88], p=0.05). However, at 3-years post-procedure, patients with diabetes had no differences in freedom from target vessel/lesion revascularization (HR 1.09, p=0.73), major adverse events (MAE; HR 1.25, p=0.36), major target limb amputation (HR 1.74, p=0.39), and death (HR 1.11, p=0.72). Conclusion: The LIBERTY 360 observed high limb preservation and low MAEs in patients with diabetes and CLTI. Higher distal embolization was observed with OA in patients with diabetes, but OR did not indicate a significant difference in risk between groups.
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Delayed cerebral ischemia (DCI) after aneurysmal subarachnoid hemorrhage (SAH) has been associated with numerous pathophysiological sequelae, including large artery vasospasm and microvascular thrombosis. The focus of this review is to provide an overview of experimental animal model studies and human autopsy studies that explore the temporal-spatial characterization and mechanism of microvascular platelet aggregation and thrombosis following SAH, as well as to critically assess experimental studies and clinical trials highlighting preventative therapeutic options against this highly morbid pathophysiological process. Upon review of the literature, we discovered that microvascular platelet aggregation and thrombosis occur after experimental SAH across multiple species and SAH induction techniques in a similar time frame to other components of DCI, occurring in the cerebral cortex and hippocampus across both hemispheres. We discuss the relationship of these findings to human autopsy studies. In the final section of this review, we highlight the important therapeutic options for targeting microvascular platelet aggregation and thrombosis, and emphasize why therapeutic targeting of this neurovascular pathology may improve patient care. We encourage ongoing research into the pathophysiology of SAH and DCI, especially in regard to microvascular platelet aggregation and thrombosis and the translation to randomized clinical trials.
Assuntos
Isquemia Encefálica/sangue , Trombose Coronária/sangue , Aneurisma Intracraniano/sangue , Microvasos/fisiopatologia , Agregação Plaquetária , Hemorragia Subaracnóidea/sangue , Animais , Isquemia Encefálica/etiologia , Trombose Coronária/etiologia , Humanos , Aneurisma Intracraniano/complicações , Hemorragia Subaracnóidea/complicaçõesRESUMO
Insects rely on specialized accessory pulsatile organs (APOs), also known as auxiliary hearts, to propel hemolymph into their antennae. In most insects, this is accomplished via the pulsations of a pair of ampulla located in the head, each of which propels hemolymph across an antenna via an antennal vessel. Once at the distal end of the appendage, hemolymph returns to the head via the antennal hemocoel. Although the structure of the antennal hearts has been elucidated in various insect orders, their hormonal modulation has only been studied in cockroaches and other hemimetabolous insects within the superorder Polyneoptera, where proctolin and FMRFamide-like peptides accelerate the contraction rate of these auxiliary hearts. Here, we assessed the hormonal modulation of the antennal APOs of mosquitoes, a group of holometabolous (Endopterygota) insects within the order Diptera. We show that crustacean cardioactive peptide (CCAP), FMRFamide and SALDKNFMRFamide increase the contraction rate of the antennal APOs and the heart of Anopheles gambiae Both antennal hearts are synchronously responsive to these neuropeptides, but their contractions are asynchronous with the contraction of the heart. Furthermore, we show that these neuropeptides increase the velocity and maximum acceleration of hemolymph within the antennal space, suggesting that each contraction is also more forceful. To our knowledge, this is the first report demonstrating that hormones of a holometabolous insect modulate the contraction dynamics of an auxiliary heart, and the first report that shows that the hormones of any insect accelerate the velocity of hemolymph in the antennal space.