Problematika kritické končetinové ischemie a buněčné léčby u syndromu diabetické nohy, patogenetické aspekty Charcotovy osteopatie. / Critical limb ischemia and autologous cell therapy in diabetic foot disease, pathogenesis of Charcot osteoarthopathy.

Němcová, Andrea

January 2020

Diabetic foot disease (DFD) is a serious complication of diabetes and, along with critical limb ischemia, significantly exacerbates the prognosis of patients. Peripheral arterial disease in patients with diabetes has an atypical clinical course, its diagnosis is challenging and is one of the most common causes of morbidity and mortality of patients with DFD. The aim of this dissertation focused on the diagnosis and treatment of DFD was to identify a suitable method for evaluating the effect of autologous cell therapy (ACT), to assess options for early diagnosis of Charcot osteoarthropathy (COA) and, possibly, to establish the association between the incidence of cardiovascular disease and DFD. In our studies concerning therapeutic vasculogenesis, we observed a significant increase in the antiangiogenic factor endostatin after ACT in contrast to its unchanged levels after standard percutaneous transluminal angioplasty; the transient increase in endostatin seems to be a marker of therapeutic vasculogenesis after ACT. A benefit of using calf muscle perfusion scintigraphy in the assessment of microcirculation and ACT effect was not clearly demonstrated. By contrast, a promising method for the evaluation of microcirculation and the effect of revascularization after ACT was MR spectroscopy of calf...

Peripheral Venous Retroperfusion: Implications for Critical Limb Ischemia and Salvage

Kemp, Arika D.

12 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Peripheral arterial disease is caused by plaque buildup in the peripheral arteries. Standard treatments are available when the blockage is proximal and focal, however when distal and diffuse the same type of the treatment options are not beneficial due to the diseased locations. Restoration of blood flow and further salvaging of the limb in these patients can occur in a retrograde manner through the venous system, called retroperfusion or arteriovenous reversal. Retroperfusion has been explored over the last century, where early side to side artery to venous connections had issues with valve competency prohibiting distal flows, edema buildup, and heart failure. However, more recent clinical studies create a bypass to a foot vein to ensure distal flows, and though the results have been promising, it requires a lengthy invasive procedure. It is our belief that the concerns of both retroperfusion approaches can be overcome in a minimally invasive/catheter based approach in which the catheter is engineered to a specific resistance that avoids edema and the perfusion location allows for valves to be passable and flow to reach distally. In this approach, the pressure flow relations were characterized in the retroperfused venous system in ex-vivo canine legs to locate the optimal perfusion location followed by in-vivo validation of canines. Six canines were acutely injured for 1-3 hours by surgical ligation of the terminal aorta and both external iliac arteries. Retroperfusion was successfully performed on five of the dogs at the venous popliteal bifurcation for approximately one hour, where flow rates at peak pressures reached near half of forward flow (37±3 vs. 84±27ml/min) and from which the slope of the P/F curves displayed a retro venous vasculature resistance that was used to calculate the optimal catheter resistance. To assess differences in regional perfusion, microspheres were passed during retroperfusion and compared to baseline microspheres passed arterially prior to occlusion in which the ratio of retroperfusion and forward perfusion levels were near the ratio of reversed and forward venous flow (0.44) throughout the limb. Decreases in critical metabolites during injury trended towards normal levels post-retroperfusion. By identifying the popliteal bifurication as a perfusion site to restore blood flow in the entirety of the distal ischemic limb, showing reversal of injury, and knowing what catheter resistances to target for further chronic studies, steps towards controlled retroperfusion and thus more efficient treatment options can be made for severe PAD patients.

Arteries -- Diseases

Atherosclerotic plaque -- Research

Blood flow -- Research

Blood flow -- Measurement

Dogs -- Anatomy -- Research

Dogs -- Blood-vessels

Ischemia -- Animal models

Blood-vessels -- Abnormalities

Hindlimb -- Abnormalities

Tissue engineering -- Research

Cardiovascular system -- Regeneration

Blood -- Circulation

Pressure -- Measurement

Myocardial reperfusion

Reperfusion (Physiology)

Biomedical engineering -- Research

Biomechanics