Plasmonic Nanophotothermal Therapy of Atherosclerosis

Heart Failure Clinical Trial

— NANOM-FIM  

Official title:

Plasmonic Photothermal Therapy of Flow-Limiting Atherosclerotic Lesions With Silica-Gold Nanoparticles: a First-in-Man Study

Clinical Trial Details — Status: Completed

Administrative data

• NCT number: NCT01270139
• Other study ID #: NANOM-FIM
• Status: Completed
• Phase: N/A
• Start date: April 1, 2007
• Est. completion date: August 1, 2016

Study information

• Verified date: February 2021
• Source: Ural State Medical University
• Contact: n/a
• Is FDA regulated: No
• Study type: Interventional

Clinical Trial Summary

The investigators hypothesize that the nanoburning is a very challenging technique to demolish and reverse the plaque especially in combination with stem cell technologies promising the functional restoration of the vessel wall.

The completed (in July 2012) interventional three arms (n=180) first-in-man trial (the NANOM-FIM trial) assessed (NCT01270139) the safety and feasibility of two delivery techniques for nanoparticles (NP), and plasmonic photothermal therapy (PPTT) of atherosclerotic lesions. Patients were assigned in a 1:1:1 ratio to receive either (1) nano-intervention with delivery of silica-gold NP in mini-surgery implanted bioengineered on-artery patch (n=60), or (2) nano-intervention with delivery of silica-gold iron-bearing NP with targeted micro-bubbles or stem cells in hands of magnetic navigation system (n=60) versus (3) stent implantation (n=60). The primary outcome was TAV at 12 months.

The observational prospective cohort analysis (an amendment to the protocol of August 29th 2012 with a decision to extend a 1-year study for another 4 years with the assessment of the 5-year clinical outcomes both retro- and prospectively) of the long-term clinical outcomes at the intention-to-treat population of 180 patients with CAD and angiographic SYNTAX score ≤22 enrolled initially to NANOM-FIM trial will be performed at 5 years after the intervention. The primary outcome will be a MACE-free survival. The secondary outcomes will be MACE, cardiac death, TLR (target lesion revascularization) and TVR (target vessel revascularization). Imaging endpoints will be assessed pre-, post- procedure and at 12-month follow-up. Clinical endpoints will be analyzed at the baseline and at 12 and 60-month follow-up (the release of results is expected after October 2016). Parameters of nanotoxicity will be assessed. The independent adjudication analysis of the clinical outcomes is scheduled in 2017-2019.

The subset post-hoc analysis will be conducted at 1- and 5-year follow-up (by the Amendment of August 29th 2012). At the first subset, patients underwent stenting with XIENCE V stent proximal to the site of nano-intervention (n=13). Subjects in the second subset were undergone drug-coated balloon pre-dilation with further nano-technique (n=20). Lesions in patients of the third subset were not prepared for the nano-approach (n=147) (neither stenting nor balloon angioplasty). The analysis will be performed and results will be released after 2018 with the same clinical outcomes.

This project and related manuscripts were not prepared or funded in any part by a commercial organization. Nanoparticles and biomedical equipment were supplied free for the study by the non-profit Agiko and De Haar Research Task Force (Rotterdam-Amsterdam, the Netherlands). All rights of the authors are reserved. The access of the international academic or governmental organizations to the essential and primary data of the trial is restricted by the Russian governmental authorities due to the interest of the Russian Federal Security Service (FSB).

Description:

Cardiovascular disease (CVD) is one of the main cause of disability and death worldwide. The underlying cause generally is atherosclerosis and more in particular thrombotic rupture of an atherosclerotic plaque in a vital artery. The restoration of blood flow to ischemic myocardium is established as the preeminent objective for the treatment of patients with CVD. Some modern angioplasty techniques generally just manipulate the form of the plaque and have some clinical and technical restrictions, relatively high complication rate and restenosis risk.

The most common techniques in current practice are angioplasty with stenting, and CABG surgery (for patients with multivessel disease). Balloon angioplasty and stenting, in fact, manage the form of the plaque and does not create a significant problem of plaque residue flowing from the site. Once a role for elective stent implantation was established, the next goal was to overcome the complications of subacute stent thrombosis (first of all, with the use of drug-eluting stents) and neointimal hyperplasia (bare-metal stents) through pharmacologic and physical means. Among unresolved issues, the investigators can describe restrictions in patients with stenosis of an unprotected left main coronary artery, multivessel disease, diabetes mellitus, still rather high rate of in-stent restenosis, and as a solution of the problem with a foreign body in a vessel, the development of biodegradable stents. Among physical obstacles for stenting, the investigators may note that atherosclerotic plaque build-up can exist in a number of different forms. The plaque can be quite hard and scaly, or more fatty and pliable. Moreover, Dr Peters D. with colleagues from Santa-Barbara (2009) published own data about new modular, multifunctional micelles that contain a targeting element, a fluorophore, and, when desired, a drug component in the same particle. Targeting atherosclerotic plaques in ApoE-KO mice fed a high-fat diet was accomplished with the pentapeptide cysteine-arginine-glutamic acid-lysine-alanine, which binds to clotted plasma proteins. The fluorescent micelles bind to the entire surface of the plaque, and notably, concentrate at the shoulders of the plaque, a location that is prone to rupture. They also show that the targeted micelles deliver an increased concentration of the anticoagulant drug hirulog to the plaque compared with untargeted micelles that may reduce bleeding complications and atherogenesis.

Moreover, the ability of statin drugs to reduce the volume of atherosclerotic plaque in the coronary artery wall, termed plaque regression, has received much attention. The statins have a remarkable track record of lowering cholesterol and improving survival. Apart from lowering low-density lipoprotein cholesterol (LDL-C) levels, they also have a multitude of other actions, often collectively described as pleiotropic effects. JUPITER (2003), REVERSAL (2004), PROVE IT (2004), ESTABLISH (2004), and ASTEROID (2006) trials have shown that low LDL levels after intensive statin therapy when accompanied by raised HDL, can regress, or partially reverse, the plaque buildup in the coronary arteries. The findings suggest that the various components of atheroma respond differently to treatment with medical therapies, and can be used to target plaques that are likely to respond. Thus, lipid pool, inflammatory reaction in the forms of cellular migration, humoral substance release, and oedema are still the most likely to be targets of pharmacotherapy. But, for instance, fibrous tissue, mineral deposits, and ground substance would seem to be irreversible despite metabolic manipulation.

Numerous devices recently have been described that utilize the application of heat to resolve atherosclerotic plaque (laser technique, electrosurgical removing of plaque, or with the use of radio frequency sparking, and others). Plasmonics is a novel invasive approach in medicine, and metal nanoparticles are a new type of optically active composite spherical one consisting of a dielectric core covered by a thin metallic shell which is typically gold. When nanoparticles are irradiated with a near-infrared laser, they absorb energy, which is quickly transferred through nonradiative relaxation into heat and accompanying effects, and eventually leads to irreparable damage of tissue. In oncology, metal nanoparticles may provide a novel means of targeted plasmonic photothermal therapy (PPTT) in tumour tissue, minimizing damage to surrounding healthy tissue. However, this approach does not use in cardiology today possessing the great potential for angioplasty. The efficiency of nanotechnologies, however, is limited by gaps in the current understanding of the thermal interactions between nanoparticles and laser light pulses or continuous waves in the context of complex biological environments. Irradiation, even with moderate pulses of energy, can induce melting, evaporation, and fragmentation of nanoparticles. These events can drastically alter the intended therapeutic effects and lead to the formation of vapour bubbles as well as acoustic waves and shock waves. But the last disadvantages can become advantages depending on the purposes of the treatment. Thus the study opens a new chapter in the history of plasmonics.

The investigators designed this study to check potent clinical opportunities, efficacy and safety of such a novel technique for angioplasty as plasmonic atherodestruction. The investigators have drawn the following research questions: 1) Is it possible to plasmonically entirely destruct a plaque with minimal complications? 2) What level of safety is typical for the different approaches if compare with stenting? 3) What are the advantages and disadvantages of the different delivery techniques - stem cells or magnetic field? 4) What is the meaning of the transplanted mesenchymal CD73+CD105+ stem-progenitor cells for atherosclerosis management? 5) Can plasmonic nanophotothermal therapy (PPTT) get an alternative to stenting?

Plasmonic photothermal therapy (PPTT) can potentially reduce the volume of plaque. PPTT melts an atherosclerotic plaque tissue with irreparable burning of targeted tissues, vapour bubbling of cellular cytoplasm and extracellular matrix with subsequent degradation of tissues, and destructive effects of acoustic and shock waves as the possible plaque-killing mechanisms. NPs are absolutely safe for an organism but entire kinetics is mostly unknown. The most dangerous approach with the lowest level of efficacy and safety is delivery of NPs with microbubbles if compare with stem cell-based one. Mesenchymal stem cells have appropriate effectiveness as a local delivery system with a lot of beneficial properties such as anti-inflammatory, anti-apoptotic, and multi-metabolic effects leading to plaque degradation. Thus, PPTT can become an alternative to stenting.

Among potential problems the investigators may name 1) technique of the delivery of these nanoparticles directly into the plaque (stem cells, aleuronic microbubbles with surfaced antibodies (as a local delivery system), direct injection or infusion into the coronary arteries and plaques during CABG or PCI); 2) high risk of acute fatal atherothrombosis at the heat site due to destruction of the fibrous cap of plaque (role of nanoparticles adhesion on the surface of endothelium); 3) long-term effects of the nanodestruction locally and in entire organism (distribution and effects of accumulation in different organs); 4) mechanism of this effect (plasmonic microexplosion and burning of tissue, lysis of cells due to vapor bubbling of cellular cytoplasm and extracellular tissues, destructive acoustic and shock waves); 5) optimal biophysical parameters and necessary energy levels of nanodetonation to prevent burning of surrounding tissues and perforation of the vessel; 6) plasmonic damage is irreparable, and it means the investigators have to combine it with another biotechnology for the restoration of vessel such as the use of stem cells; 7) optimal type of stem cells (source, origin, level of differentiation, potential, properties).

So, disadvantages of current low-invasive approaches (stenting, statin drugs, and others, laser, electrosurgery devices):

• Foreign body in the heart

• Restenosis, including neointimal hyperplasia (adventitial and circulating stem-progenitor cells of different origin are involved)

• Risk of fatal acute or sub-acute atherothrombosis (including 'in-stent' sub-acute atherothrombosis)

• Non-pathogenetic - cannot reverse or significantly regress the plaque

• No effect for remodeling and calcification (restriction for necessary remodeling)

• Clinical restrictions for some group (multivessel disease, left main CAD, diabetes mellitus, severe CAD and etc), on another hand, CABG is a very traumatic procedure (solution - MICS, including achievements in endoscopic stereotaxic surgery), but CABG is still an approach in charge in severe or high-risk patients

Disadvantages of the studied approach:

• The necessity of the special delivery technique

• The lost function of the artery - irreparable pro-fibrotic damage - the necessity of another clinical management for restoration of tissue - the necessity of the restoration therapy with stem cells

• The threat of acute fatal atherothrombosis due to rupture of (vulnerable) plaque

• Cannot treat non-organic part of plaque - the necessity of the special therapy - stem cells

• The harm of potent detrimental side-effects - vapour bubbling (boiling of cytoplasm and ECM with subsequent lysis of cells, and provocation of pro-apoptotic cascades), acoustic and shock waves due to the plasma-generated laser-related detonation of nanoshells in tissue

• Erratic (uncontrollable) heating - surrounding tissue of the site of interest can achieve a temperature until 38-39°. But at the site of burning final temperature can be at about 50-180 C (cauterization/ searing/ melting effect) with following the pro-fibrous effect of tissue.

Recruitment information / eligibility

• Status: Completed
• Enrollment: 180
• Est. completion date: August 1, 2016
• Est. primary completion date: April 1, 2009
• Accepts healthy volunteers: No
• Gender: All
• Age group: 45 Years to 65 Years

Eligibility

Inclusion Criteria:

• age 45-65 years old

• male and female

• single- or multi-vessel CAD with flow-limiting lesions

• no indications for coronary artery bypass surgery (CABG)

• stable angina with indications for percutaneous coronary interventions (PCI)

• NYHA (New York Heart Association) I-III functional class of heart failure (HF)

• treated hypertension (in supine position: systole >140 mm Hg, diastole >90 mm Hg)

• de novo treated.

Exclusion Criteria:

• non-compliance,

• angiographic SYNTAX score =23

• history of myocardial infarction (MI), unstable angina, PCI or CABG, atrial fibrillation or other dysrhythmias, stroke

• presence of indications for CABG

• presence of contraindications for PCI or CABG

• NYHA IV functional class of HF

• diabetes mellitus (in case of fasting glucose >7.0 mM/L or random glucose >11.0 mM/L)

• untreated hypertension

• asthma

• known hypersensitivity or contraindications to anti-platelet drugs

• contrast sensitivity

• participation to any drug- or intervention-investigation during the previous 60 days

Related Conditions & MeSH terms

• Angina, Stable
• Atherosclerosis
• Coronary Artery Disease
• Heart Failure
• Multivessel Coronary Artery Disease
• Stable Angina

Intervention

Procedure:
• Transplantation of nanoparticles
60 patients into nanogroup with the use of 60/15-70/40 nm silica-gold nanoparticles (NPs) transplanted by endoscopic cardiac surgery in the composition of bioengineered on-artery patch grown on the basis of biopolymeric scaffold and host circulating CD45-CD34-CD73+CD105+ progenitor cells
• Transplantation of iron-bearing nanoparticles
60 - into ferro-magnetic group with 60/15-70/40 nm silica-gold iron-bearing NPs with delivery in hand of magnetic navigation system

Device:
• Stenting
60 - in sirolimus-eluting stenting control

Locations

Country	Name	City	State
Netherlands	De Haar Research Task Force	Amsterdam	North Holland
Russian Federation	Transfiguration Clinic	Yekaterinburg	Sverdlovsk Oblast
Russian Federation	Ural Center of Modern Nanotechnologies, Institute of Natural Sciences, Ural Federal University	Yekaterinburg	Sverdlovsk Oblast
Russian Federation	Ural Institute of Cardiology	Yekaterinburg	Sverdlovsk Oblast

Sponsors (5)

Lead Sponsor	Collaborator
Ural State Medical University	De Haar Research Task Force, Transfiguration Clinic, Ural Federal University, Ural Institute of Cardiology

Countries where clinical trial is conducted

Netherlands,  Russian Federation, 

References & Publications (7)

Kharlamov AN, Feinstein JA, Cramer JA, Boothroyd JA, Shishkina EV, Shur V. Plasmonic photothermal therapy of atherosclerosis with nanoparticles: long-term outcomes and safety in NANOM-FIM trial. Future Cardiol. 2017 Jul;13(4):345-363. doi: 10.2217/fca-201 — View Citation

Kharlamov AN, Gabinsky JL. Plasmonic photothermic and stem cell therapy of atherosclerotic plaque as a novel nanotool for angioplasty and artery remodeling. Rejuvenation Res. 2012 Apr;15(2):222-30. doi: 10.1089/rej.2011.1305. — View Citation

Kharlamov AN, Tyurnina AE, Veselova VS, Kovtun OP, Shur VY, Gabinsky JL. Silica-gold nanoparticles for atheroprotective management of plaques: results of the NANOM-FIM trial. Nanoscale. 2015 May 7;7(17):8003-15. doi: 10.1039/c5nr01050k. — View Citation

Kharlamov AN, Zubarev IV, Shishkina EV, Shur VY. Nanoparticles for treatment of atherosclerosis: challenges of plasmonic photothermal therapy in translational studies. Future Cardiol. 2018 Mar;14(2):109-114. doi: 10.2217/fca-2017-0051. Epub 2018 Jan 16. Review. — View Citation

Kharlamov AN. Cardiovascular burden and percutaneous interventions in Russian Federation: systematic epidemiological update. Cardiovasc Diagn Ther. 2017 Feb;7(1):60-84. doi: 10.21037/cdt.2016.08.10. Review. — View Citation

Kharlamov AN. Glimpse into the Future of Nanotheranostic Strategies for Regression of Atherosclerosis through the Prism of Systems Biomedicine: Systematic Review of Innovations from Multifunctional Nanoformulations to Devices on Chip. Current Nanomedicine 6(3): 186-218, 2016. doi: 10.2174/2468187306666161121142756.

Kharlamov AN. Plasmonic photothermal therapy for atheroregression below Glagov threshold. Future Cardiol. 2013 May;9(3):405-25. doi: 10.2217/fca.13.16. Review. — View Citation

Outcome

Type	Measure	Description	Time frame	Safety issue
Primary	Total Atheroma Volume	Total atheroma volume (TAV, plaque-media volume, mm3) at 12 months. Quantitative coronary angiography (QCA) and Intravascular Ultrasound (IVUS) were performed pre-, post-procedure and at 12-month follow-up after a bolus infusion of i.c. nitrate. QCA was undergone with the CAAS II analysis system (Pie Medical B.V., Maastricht, The Netherlands) with analysis of different QCA parameters such as minimal lumen diameter, maximum lumen diameter, reference diameter, diameter stenosis, lesion length, percent atheroma volume (PAV), total atheroma volume (TAV), and lumen volume.	at 12-month follow-up
Primary	MACE (Major Adverse Cardiovascular Events)-Free Survival	MACE (major adverse cardiovascular events)-free survival reflects per cent of survived patients without MACE. An amendment to the protocol was approved on August 29th 2012 with a decision to extend a 1-year study for another 4 years with the assessment of the 5-year clinical outcomes both retro- and prospectively.	at 60 months follow-up
Secondary	Per Cent of Fibro-fatty Component	IVUS (intravascular ultrasound) and IVUS-VH (virtual histology) images were acquired simultaneously with a phased array 20 MHz intravascular ultrasound catheter EagleEye (Volcano Co., Rancho Cordova, CA, USA) with motorized pull-back at a constant speed of 0.5 mm/s. Four tissue components (necrotic core - red; dense calcium - white; fibrous - green; and fibro-fatty - light green or yellow) were identified with autoregressive classification systems. For each cross section stent struts were detected as areas of apparent dense calcium and necrotic core. All IVUS analysis was performed offline by a CoreLab of the Ural Institute of Cardiology.	at 12-month follow-up
Secondary	Event Free Survival	The Kaplan-Meier analysis of the cardiac event-free survival (failure-free survival). The end point in this study was cardiac event-free survival during follow-up, starting at randomization. Cardiac events included cardiac death, myocardial infarction and unintended revascularization. Cardiac death was defined as sudden death, death after the onset of symptoms suggestive of cardiac ischemia and death due to heart failure. Noncardiac death was defined as death due to all other causes. Myocardial infarction was defined as an increase in cardiac enzymes or new pathologic Q-waves on the ECG, or both. Unintended revascularization was defined as PTCA or CABG performed due to worsening of the patient's clinical condition, rather than the PTCA or CABG assigned by the revascularization team when patient management was determined.	at 12-month follow-up
Secondary	Restenosis Rate	Restenosis (stenosis>50%) rate	at 12-month follow-up
Secondary	Late Definite Thrombosis	Late definite thrombosis rate	at 12-month follow-up
Secondary	Coronary Vasomotion - Mean Lumen Diameter After Infusion of Acetylcholine 10-6 M	Coronary vasomotion was assessed with QCA. End-diastolic images of coronary arteries were evaluated at baseline, after intravascular infusion of acetylcholine (through a microcatheter at increasing doses up to 10-8, 10-7, 10-6 M with a washout period of at least five minutes between each dose), and after nitroglycerine application following acetylcholine (100 µg orally). In all patients, measurements were performed in two segments on site of intervention while 960 seconds. The artery diameter was calibrated against the contrast-filled tip of the catheter. Vasoconstriction to acetylcholine was defined as a 3% change of the mean lumen diameter after infusion of the maximal dose of acetylcholine. An investigator blinded to treatment group performed all measurements.	at 12-month follow-up
Secondary	Per Cent Atheroma Volume	Per cent atheroma volume (PAV, plaque burden, %). Quantitative coronary angiography (QCA) and Intravascular Ultrasound (IVUS) were performed pre-, post-procedure and at 12-month follow-up after a bolus infusion of i.c. nitrate. QCA was undergone with the CAAS II analysis system (Pie Medical B.V., Maastricht, The Netherlands) with analysis of different QCA parameters such as minimal lumen diameter, maximum lumen diameter, reference diameter, diameter stenosis, lesion length, percent atheroma volume (PAV), total atheroma volume (TAV), and lumen volume.	at 12-month follow-up
Secondary	Target Lesion Revascularization	Target lesion revascularization, per cent	at 12-month follow-up
Secondary	Per Cent of Fibrous Component	IVUS (intravascular ultrasound) and IVUS-VH (virtual histology) images were acquired simultaneously with a phased array 20 MHz intravascular ultrasound catheter EagleEye (Volcano Co., Rancho Cordova, CA, USA) with motorized pull-back at a constant speed of 0.5 mm/s. Four tissue components (necrotic core - red; dense calcium - white; fibrous - green; and fibro-fatty - light green or yellow) were identified with autoregressive classification systems. For each cross section stent struts were detected as areas of apparent dense calcium and necrotic core. All IVUS analysis was performed offline by a CoreLab of the Ural Institute of Cardiology.	at 12-month follow-up
Secondary	Per Cent of Necrotic Core	IVUS (intravascular ultrasound) and IVUS-VH (virtual histology) images were acquired simultaneously with a phased array 20 MHz intravascular ultrasound catheter EagleEye (Volcano Co., Rancho Cordova, CA, USA) with motorized pull-back at a constant speed of 0.5 mm/s. Four tissue components (necrotic core - red; dense calcium - white; fibrous - green; and fibro-fatty - light green or yellow) were identified with autoregressive classification systems. For each cross section stent struts were detected as areas of apparent dense calcium and necrotic core. All IVUS analysis was performed offline by a CoreLab of the Ural Institute of Cardiology.	at 12-month follow-up
Secondary	Per Cent of Calcium	IVUS (intravascular ultrasound) and IVUS-VH (virtual histology) images were acquired simultaneously with a phased array 20 MHz intravascular ultrasound catheter EagleEye (Volcano Co., Rancho Cordova, CA, USA) with motorized pull-back at a constant speed of 0.5 mm/s. Four tissue components (necrotic core - red; dense calcium - white; fibrous - green; and fibro-fatty - light green or yellow) were identified with autoregressive classification systems. For each cross section stent struts were detected as areas of apparent dense calcium and necrotic core. All IVUS analysis was performed offline by a CoreLab of the Ural Institute of Cardiology.	at 12-month follow-up
Secondary	Minimal Lumen Diameter	Minimal lumen diameter (MLD, mm)	at 12-month follow-up
Secondary	MACE	MACE includes per cent of patients with cardiac death. STEMI (ST-elevation myocardial infarction), non-STEMI, and TLR (target lesion revascularization). An amendment to the protocol was approved on August 29th 2012 with a decision to extend a 1-year study for another 4 years with the assessment of the 5-year clinical outcomes both retro- and prospectively.	at 60 months follow-up
Secondary	Cardiac Death	Cardiac death includes per cent of patients passed away due to any cardiac death. An amendment to the protocol was approved on August 29th 2012 with a decision to extend a 1-year study for another 4 years with the assessment of the 5-year clinical outcomes both retro- and prospectively.	at 60 months follow-up
Secondary	TLR (Target Lesion Revascularization)	TLR (target lesion revascularization) reflects per cent of patients with TLR. An amendment to the protocol was approved on August 29th 2012 with a decision to extend a 1-year study for another 4 years with the assessment of the 5-year clinical outcomes both retro- and prospectively.	at 60 months follow-up
Secondary	TVR (Target Vessel Revascularization)	TVR (target vessel revascularization) reflects per cent of patients with TVR. An amendment to the protocol was approved on August 29th 2012 with a decision to extend a 1-year study for another 4 years with the assessment of the 5-year clinical outcomes both retro- and prospectively.	at 60 months follow-up
Secondary	Mean Number of Membrane Defects on Membrane of Red Blood Cells	Mean number of membrane defects on membrane of red blood cells calculated with atomic force microscopy (AFM) in random patients. An amendment to the protocol was approved on August 29th 2012 with a decision to extend a 1-year study for another 4 years with the assessment of the 5-year clinical outcomes both retro- and prospectively.	at 60 months follow-up

External Links

•   De Haar Research Task Force
•   Transfiguration Clinic
•   Ural Center of Modern Nanotechnologies, Institute of Natural Sciences, Ural Federal University
•   Ural Institute of Cardiology
•   Ural State Medical University