Takaharu Nakayoshi

Coronary Endothelial Dysfunction Distal to Stent of First-Generation Drug-Eluting Stents

OBJECTIVES This study sought to evaluate the relationship between coronary endothelial function and neointimal coverage after drug-eluting stent (DES) implantation. BACKGROUND The mechanisms of endothelial dysfunction after DES implantation remain to be fully elucidated. We hypothesized that poor neointimal coverage after DES implantation may be associated with endothelial dysfunction distal to the stent site. METHODS Sixty-six stable angina patients treated with a first-generation DES were enrolled. At 9-month follow-up, coronary endothelial function was evaluated with intracoronary infusion of incremental doses of acetylcholine (10(-8), 10(-7), and 10(-6) mol/l) and nitroglycerin (200 μg). Vascular responses at the segments proximal and distal to the stent site were angiographically and quantitatively measured. At the same time, the degree of neointimal coverage was evaluated using coronary angioscopy and classified into 4 grades: 0 (no coverage) to 3 (full coverage). RESULTS We divided the subjects into poor-coverage (grades 0 to 1, n = 33) and good-coverage (grades 2 to 3, n = 33) groups. Acetylcholine induced dose-dependent coronary vasoconstrictions in both groups. At the segment distal to the stent, the magnitude of vasoconstriction to acetylcholine in the poor-coverage group was significantly greater than in the good-coverage group (p < 0.001), whereas vasomotor responses proximal to the stent and vasodilation by nitroglycerine were similar between the 2 groups. CONCLUSIONS Coronary endothelial dysfunction distal to the stent was associated with poor neointimal coverage after DES implantation.

Platelet-derived microparticles augment the adhesion and neovascularization capacities of circulating angiogenic cells obtained from atherosclerotic patients

OBJECTIVE The neovascularization-related capacities of circulating angiogenic cells (CACs) are impaired in atherosclerotic patients, which may explain the unsatisfactory effects of therapeutic angiogenesis with atherosclerotic patient-derived CACs. Platelet-derived microparticles (PMPs) were reported to augment the re-endothelialization capacity of CACs. Accordingly, we investigated whether PMPs could augment the neovascularization-related capacities of atherosclerotic patient-derived CACs in vitro and in vivo and if so, the associated mechanisms. METHODS AND RESULTS We isolated mononuclear cells and PMPs from atherosclerotic patient-derived peripheral blood and generated PMP-pretreated CACs (PMP-CACs) by co-culture of the mononuclear cells and PMPs. Although the migration capacity of PMP-CACs was similar to that of CACs, the adhesion capacity of PMP-CACs was greater. PMPs released RANTES into the culture medium, and the receptors were similarly expressed on the surfaces of CACs and PMP-CACs. Intravenous injection of PMP-CACs to rats with hindlimb ischemia augmented neovascularization of the ischemic limbs more than the injection of CACs. The number of PMP-CACs incorporated into the capillaries of the ischemic limbs was greater than that of incorporated CACs. The augmented adhesion and neovascularization capacities by PMP-CACs were canceled out by a RANTES neutralizing antibody. CONCLUSIONS PMP-secreted RANTES may play a role in the augmenting adhesion and neovascularization capacities of CACs. Injection of PMP-CACs may be a new strategy to augment the effects of therapeutic angiogenesis for limb ischemia in atherosclerotic patients.

Augmented neovascularization with magnetized endothelial progenitor cells in rats with hind-limb ischemia

Augmenting neovascularization with the use of endothelial progenitor cells (EPCs) is a therapeutic option to rescue critical limb ischemia (CLI). However, the outcomes have been not so satisfactory. The detectable number of injected EPCs at the ischemic site is rather small. If EPCs accumulate more and stay longer there, neovascularization will be augmented. In this study, we tested whether external magnetic forces (EMFs) accumulated magnetized EPCs (Mag-EPCs) at the ischemic site and thereby augmented neovascularization. We cultured peripheral blood-derived mononuclear cells to obtain EPCs and generated Mag-EPCs by a magnetofection method with nanoparticles. Prussian-blue staining revealed magnetic nanoparticles incorporated into the cytoplasms and nuclei of Mag-EPCs. The survival rate of Mag-EPCs at day 9 of culture was 98.7%, indicating no cell toxicity of magnetic nanoparticles. EMFs augmented adhesion capacity of Mag-EPCs not only in the static but also in the flow condition in vitro, compared to without EMFs. The migration capacity of Mag-EPCs with EMFs was 160% more than EPCs or Mag-EPCs without them. After an intravenous injection of Mag-EPCs into the rat with hind-limb ischemia, the recovery of blood flow and capillary density in the ischemic limb were significantly more (p<0.01) with EMFs than without them. EMFs augmented neovascularization capacity of Mag-EPCs compared to EPCs alone. This method could be a new therapeutic strategy for patients with CLI.

Differential angioscopic findings of neointimal coverage among first-, second-, and next generation drug-eluting stents.

Article history: Received 21 July 2016 Accepted 7 August 2016 Available online 9 August 2016 markedly yellow plaques (45%) were observed by angioscopy (N = 24 patients; Panel 1A and B). In the second generation DES, white but thin neointimal coverage of stent struts was observed as a transparent and homogeneous layer with less thrombi (20% of patients) or yellow plaques (20%) (N = 24 patients; Panel 2A–C), an indication of better neointimal coverage than first-generation DES.

Optical frequency-domain imaging and pulmonary angioscopy in chronic thromboembolic pulmonary hypertension.

Unresolved thromboemboli in the pulmonary arteries (PAs) cause chronic thromboembolic pulmonary hypertension (CTEPH), which is usually diagnosed by mismatched perfusion defects on ventilation-perfusion lung scintigraphy and chronic thromboembolic signs on computed tomography (CT) scan and/or conventional pulmonary angiography. In our recent three cases of CTEPH (Case 1; …

FOXO4-knockdown suppresses oxidative stress-induced apoptosis of early pro-angiogenic cells and augments their neovascularization capacities in ischemic limbs.

The effects of therapeutic angiogenesis by intramuscular injection of early pro-angiogenic cells (EPCs) to ischemic limbs are unsatisfactory. Oxidative stress in the ischemic limbs may accelerate apoptosis of injected EPCs, leading to less neovascularization. Forkhead transcription factor 4 (FOXO4) was reported to play a pivotal role in apoptosis signaling of EPCs in response to oxidative stress. Accordingly, we assessed whether FOXO4-knockdown EPCs (FOXO4KD-EPCs) could suppress the oxidative stress-induced apoptosis and augment the neovascularization capacity in ischemic limbs. We transfected small interfering RNA targeted against FOXO4 of human EPCs to generate FOXO4KD-EPCs and confirmed a successful knockdown. FOXO4KD-EPCs gained resistance to apoptosis in response to hydrogen peroxide in vitro. Oxidative stress stained by dihydroethidium was stronger for the immunodeficient rat ischemic limb tissue than for the rat non-ischemic one. Although the number of apoptotic EPCs injected into the rat ischemic limb was greater than that of apoptotic EPCs injected into the rat non-ischemic limb, FOXO4KD-EPCs injected into the rat ischemic limb brought less apoptosis and more neovascularization than EPCs. Taken together, the use of FOXO4KD-EPCs with resistance to oxidative stress-induced apoptosis may be a new strategy to augment the effects of therapeutic angiogenesis by intramuscular injection of EPCs.

Interleukin-1β is associated with coronary endothelial dysfunction in patients with mTOR-inhibitor-eluting stent implantation

Implantation of mammalian target of rapamycin (mTOR)-inhibitor drug-eluting stents (DESs) impairs coronary endothelial function. There are no known non-invasive biomarkers of coronary endothelial dysfunction. We aimed to assess the association between serum interleukin-1beta (IL-1β) and coronary endothelial dysfunction in patients with mTOR-inhibitor DES implantation and to investigate the association between the mTOR pathway and IL-1β. We enrolled 35 patients who had implanted DESs for coronary artery disease. At a 10-month follow-up, peripheral venous blood samples were collected to measure IL-1β levels. Coronary endothelial dysfunction was evaluated by intracoronary infusion of incremental doses of acetylcholine. Serum IL-1β levels were significantly associated with the magnitude of vasoconstriction to acetylcholine at the segment distal (P < 0.05) but not proximal to the stent. Serum IL-1β levels were positively correlated with stent length (P < 0.05). To examine the direct effects of mTOR inhibition on IL-1β release, sirolimus was incubated in cultured human umbilical vein endothelial cells (HUVECs) or coronary artery smooth muscle cells (CASMCs). Sirolimus directly increased IL-1β mRNA expression (P < 0.01) and enhanced IL-1β release into the culture media (P < 0.01) in CASMCs, but not in HUVECs. Inhibition of mTOR triggers IL-1β release through transcriptional activation in CASMCs. Serum IL-1β levels are a potential biomarker for mTOR-inhibitor DES-associated coronary endothelial dysfunction.

Pulmonary artery dysfunction in chronic thromboembolic pulmonary hypertension

Background Unresolved thromboemboli in the pulmonary arteries (PA) is known to cause chronic thromboembolic pulmonary hypertension (CTEPH). However, it remains unknown if vascular dysfunction in pulmonary arteries exists in patients with CTEPH. Methods and results We enrolled 7 female patients with CTEPH in this study, who have stable pulmonary hemodynamics after balloon pulmonary angioplasty (age; 73.6 ± 3.0 years old, mean right atrial pressure; 4.1 ± 0.4 mm Hg, mean pulmonary arterial pressure; 29.4 ± 2.7, mean pulmonary artery wedge pressure; 8.1 ± 1.2, pulmonary vascular resistance; 397.3 ± 51.7 dynes, cardiac index; 3.1 ± 0.2 L/min/m2). Pulmonary artery vascular function was evaluated by measuring pulmonary artery vasomotion in response to acetylcholine (Ach) at 10-month follow-up after balloon pulmonary angioplasty. All pulmonary vasoactive drugs were discontinued on the day of the procedures. The endothelium-dependent vasomotor response was evaluated by intra-pulmonary artery infusion of Ach at the dose of 10− 8 mol/l, and the vaso-spastic response was at 10− 6 mol/l. We evaluated vasomotor responses at the same segment in each patient, by measuring % changes of luminal area detected by quantitative pulmonary arterial optical frequency-domain imaging (OFDI), where OFDI catheter was fixed during the procedure. Endothelial dysfunction was observed at the dose of Ach at 10− 8 mol/l and vasoconstriction was also confirmed at the dose of Ach at 10− 6 mol/l in the diseased pulmonary arteries in CTEPH. Conclusions These results indicated that the pulmonary artery dysfunction exists in patients with CTEPH, which may be involved in the pathogenesis and progression of CTEPH.

Hybrid training system-induced myokine secretion in healthy men

HighlightsFifty‐two cytokines were measured before and after exercise of the lower limbs.The exercise was composed of volitional and electrical muscle contractions.The muscle contraction was controlled by the special “Hybrid Training System”.The exercise increased serum CTACK, erythropoietin, and TRAIL.Previous reports imply the cytokines as therapeutic myokines. Abstract The hybrid training system (HTS) is a special and compact system for effective skeletal muscle training by a combined application of volitional and electrical muscle contraction. Lower limbs’ muscle training using HTS has been reported to increase not only muscle strength but also plasma interleukin‐6 levels; however, little is known in other cytokines. In this study, we measured 52 cytokines and creatine phosphokinase‐MM in the serum of 16 healthy men before and after lower limbs’ muscle training by the knee flexion and extension using HTS. Skeletal muscle volume‐corrected serum concentrations of cutaneous T‐cell‐attracting chemokine, erythropoietin, and tumor necrosis factor‐related apoptosis‐inducing ligand increased immediately after the training. These increased cytokines have been reported to play important roles in wound healing, neuroprotection, and cardiovascular protection.

Cardiac cycle-synchronized electrical muscle stimulator for lower limb training with the potential to reduce the heart's pumping workload

Background The lower limb muscle may play an important role in decreasing the heart’s pumping workload. Aging and inactivity cause atrophy and weakness of the muscle, leading to a loss of the heart-assisting role. An electrical lower limb muscle stimulator can prevent atrophy and weakness more effectively than conventional resistance training; however, it has been reported to increase the heart’s pumping workload in some situations. Therefore, more effective tools should be developed. Methods We newly developed a cardiac cycle-synchronized electrical lower limb muscle stimulator by combining a commercially available electrocardiogram monitor and belt electrode skeletal muscle electrical stimulator, making it possible to achieve strong and wide but not painful muscle contractions. Then, we tested the stimulator in 11 healthy volunteers to determine whether the special equipment enabled lower limb muscle training without harming the hemodynamics using plethysmography and a percutaneous cardiac output analyzer. Results In 9 of 11 subjects, the stimulator generated diastolic augmentation waves on the dicrotic notches and end-diastolic pressure reduction waves on the plethysmogram waveforms of the brachial artery, showing analogous waveforms in the intra-aortic balloon pumping heart-assisting therapy. The heart rate, stroke volume, and cardiac output significantly increased during the stimulation. There was no change in the systolic or diastolic blood pressure during the stimulation. Conclusion Cardiac cycle-synchronized electrical muscle stimulation for the lower limbs may enable muscle training without harmfully influencing the hemodynamics and with a potential to reduce the heart’s pumping workload, suggesting a promising tool for effectively treating both locomotor and cardiovascular disorders.