Noninvasive arterial thrombus imaging with 99mTc monoclonal antifibrin antibody

The evolution of fibrin-specific targeting strategies

Fibrin-specific targeting capabilities have been highly sought for over 50 years due to their implications for bio-molecule delivery, diagnostics, and regenerative medicine. Yet only recently has our full knowledge of fibrin's complex polymerization dynamics and biological interactions begun to be fully exploited in pursuit of this goal. This highlight will discuss the range of rapidly changing strategies for specifically targeting fibrin over the precursor fibrinogen and the advantages and disadvantages of these approaches for various applications.

In vivo molecular imaging of thrombosis and thrombolysis using a fibrin-binding positron emission tomographic probe

BACKGROUND

Fibrin is a major component of arterial and venous thrombi and represents an ideal candidate for molecular imaging of thrombosis. Here, we describe imaging properties and target uptake of a new fibrin-specific positron emission tomographic probe for thrombus detection and therapy monitoring in 2 rat thrombosis models.

METHODS AND RESULTS

The fibrin-binding probe FBP7 was synthesized by conjugation of a known short cyclic peptide to a cross-bridged chelator (CB-TE2A), followed by labeling with copper-64. Adult male Wistar rats (n=26) underwent either carotid crush injury (mural thrombosis model) or embolic stroke (occlusive thrombosis model) followed by recombinant tissue-type plasminogen activator treatment (10 mg/kg, IV). FBP7 detected thrombus location in both animal models with a high positron emission tomographic target-to-background ratio that increased over time (>5-fold at 30-90 minutes, >15-fold at 240-285 minutes). In the carotid crush injury animals, biodistribution analysis confirmed high probe uptake in the thrombotic artery (≈0.5%ID/g; >5-fold greater than blood and other tissues of the head and thorax). Similar results were obtained from ex vivo autoradiography of the ipsilateral versus contralateral carotid arteries. In embolic stroke animals, positron emission tomographic-computed tomographic imaging localized the clot in the internal carotid/middle cerebral artery segment of all rats. Time-dependent reduction of activity at the level of the thrombus was detected in recombinant tissue-type plasminogen activator-treated rats but not in vehicle-injected animals. Brain autoradiography confirmed clot dissolution in recombinant tissue-type plasminogen activator-treated animals, but enduring high thrombus activity in control rats.

CONCLUSIONS

We demonstrated that FBP7 is suitable for molecular imaging of thrombosis and thrombolysis in vivo and represents a promising candidate for bench-to-bedside translation.

Evaluation of 99mTc-labeled cyclic RGD peptide with a PEG4 linker for thrombosis imaging: comparison with DMP444

DMP444 is a (99m)Tc-labeled cyclic RGD peptide, which has been evaluated in preclinical canine deep vein thrombosis (DVT) and pulmonary embolism (PE) models, and in patients with DVT and PE by SPECT (single photon emission computed tomography). Clinical data indicated that DMP444 is useful for imaging DVT, but it had limited utility for imaging PE in patients. To understand its clinical findings, we prepared a new radiotracer P4-DMP444 by replacing the lipophilic 6-aminocaproic acid (CA) in DMP444 with a highly water-soluble PEG(4) (15-amino-4,7,10,13-tetraoxapentadecanoic acid) linker. The objective of this study was to explore the impact of PEG(4) on biological properties (biodistribution, excretion kinetics, and capability to image thrombi) of (99m)Tc radiotracer. We also used canine DVT and PE models to perform imaging studies with/without the heparin pretreatment. These studies were specifically designed to explore the impact of heparin treatment on thrombosis uptake of P4-DMP444. It was found that replacing the CA linker with PEG(4) could enhance the radiotracer clearance kinetics from blood and normal organs in both rats and dogs. The fact that P4-DMP444 and DMP444 share very similar thrombosis uptake in both DVT and PE models suggests that the PEG(4) linker has little effect on GPIIb/IIIa binding affinity of cyclic RGD peptide. Even though P4-DMP444 had less accumulation than DMP444 in the blood, heart, lungs, and muscle over the 2 h study period in both rats and dogs, the difference in PE/lung and DVT/muscle ratios is marginal, suggesting that one PEG(4) linker is not sufficient to dramatically change the contrast between thrombus and background. It is very important to note that the heparin treatment of dogs with DVT and PE resulted in dramatic decrease in accumulation of P4-DMP444 in fresh thrombi. On the basis of these results, we believe that DMP444 and P4-DMP444 are excellent radiotracers for imaging both DVT and PE, and should be used in patients without antithrombosis treatment at the time of imaging.

Radiolabeled Cyclic RGD Peptides as Radiotracers for Imaging Tumors and Thrombosis by SPECT

The integrin family is a group of transmembrane glycoprotein comprised of 19 α- and 8 β-subunits that are expressed in 25 different α/β heterodimeric combinations on the cell surface. Integrins play critical roles in many physiological processes, including cell attachment, proliferation, bone remodeling, and wound healing. Integrins also contribute to pathological events such as thrombosis, atherosclerosis, tumor invasion, angiogenesis and metastasis, infection by pathogenic microorganisms, and immune dysfunction. Among 25 members of the integrin family, the α(v)β(3) is studied most extensively for its role of tumor growth, progression and angiogenesis. In contrast, the α(IIb)β(3 )is expressed exclusively on platelets, facilitates the intercellular bidirectional signaling ("inside-out" and "outside-in") and allows the aggregation of platelets during vascular injury. The α(IIb)β(3) plays an important role in thrombosis by its activation and binding to fibrinogen especially in arterial thrombosis due to the high blood flow rate. In the resting state, the α(IIb)β(3) on platelets does not bind to fibrinogen; on activation, the conformation of platelet is altered and the binding sites of α(IIb)β(3 )are exposed for fibrinogen to crosslink platelets. Over the last two decades, integrins have been proposed as the molecular targets for diagnosis and therapy of cancer, thrombosis and other diseases. Several excellent review articles have appeared recently to cover a broad range of topics related to the integrin-targeted radiotracers and their nuclear medicine applications in tumor imaging by single photon emission computed tomography (SPECT) or a positron-emitting radionuclide for positron emission tomography (PET). This review will focus on recent developments of α(v)β(3)-targeted radiotracers for imaging tumors and the use of α(IIb)β(3)-targeted radiotracers for thrombosis imaging, and discuss different approaches to maximize the targeting capability of cyclic RGD peptides and improve the radiotracer excretion kinetics from non-cancerous organs. Improvement of target uptake and target-to-background ratios is critically important for target-specific radiotracers.

Radionuclide imaging: a molecular key to the atherosclerotic plaque

Despite primary and secondary prevention, serious cardiovascular events such as unstable angina or myocardial infarction still account for one-third of all deaths worldwide. Therefore, identifying individual patients with vulnerable plaques at high risk for plaque rupture is a central challenge in cardiovascular medicine. Several noninvasive techniques, such as magnetic resonance imaging, multislice computed tomography, and electron beam tomography are currently being tested for their ability to identify such patients by morphological criteria. In contrast, molecular imaging techniques use radiolabeled molecules to detect functional aspects in atherosclerotic plaques by visualizing their biological activity. Based upon the knowledge about the pathophysiology of atherosclerosis, various studies in vitro and in vivo and the first clinical trials have used different tracers for plaque imaging studies, including radioactive-labeled lipoproteins, components of the coagulation system, cytokines, mediators of the metalloproteinase system, cell adhesion receptors, and even whole cells. This review gives an update on the relevant noninvasive plaque imaging approaches using nuclear imaging techniques to detect atherosclerotic vascular lesions.

Molecular imaging of vulnerable atherosclerotic plaques

Despite primary and secondary prevention, serious cardiovascular events such as unstable angina or myocardial infarction still account for a third of all deaths worldwide. Therefore, identifying individual patients with vulnerable plaques at high risk for plaque rupture is a central challenge in clinical medicine. Several noninvasive techniques, such as magnetic resonance imaging, multislice computed tomography and electron beam tomography are currently being tested for their ability to identify such patients by morphological criteria. In contrast, noninvasive scintigraphic techniques use radiolabeled molecules to detect functional aspects in atherosclerotic plaques by visualizing its biologic activity. Based upon knowledge regarding the pathophysiology of atherosclerosis, various studies - in vitro, in vivo and first clinical trials - have used different tracers for plaque imaging studies, including radioactive labeled lipoproteins, components of the coagulation system, cytokines, mediators of the metalloproteinase system, cell adhesion receptors and even whole cells.

Targeting the vulnerable plaque: the evolving role of nuclear imaging

The majority of acute ischemic events relating to atherosclerosis are caused by plaque rupture and ensuing thrombosis. The risk of plaque rupture is dictated in part by plaque morphology, which in turn is influenced by pathophysiologic mechanisms at the cellular and molecular level. Anatomic imaging modalities such as intravascular ultrasound, high-resolution magnetic resonance imaging, and multislice computed tomography can identify morphologic features of the vulnerable plaque, such as a large lipid core and thin fibrous cap, but give little or no information regarding molecular and cellular mechanisms, such as endothelial function, macrophage activation, lipid transport and metabolism, and cell death. Recent studies suggest that nuclear imaging may be able to provide images of sufficient quality to identify and quantify some of these molecular and cellular pathophysiologic processes. In the future this could allow for the early identification and noninvasive monitoring of vulnerable plaque.

Improved imaging of deep venous thrombi during anticoagulation using radiolabelled anti-D-dimer antibodies

OBJECTIVES

Radiolabelled anti-fibrin antibodies have not yet enabled reliable and practical diagnosis of venous thromboembolism. However, previous unsuccessful clinical trials were performed with anti-fibrin beta-chain antibodies that do not optimally bind to thrombi during anticoagulation. The current experiments were performed to determine if radiolabelled anti-D-dimer antibodies more reliably allowed nuclear medicine imaging of deep venous thrombi during anticoagulation than anti-beta-chain antibodies.

METHODS

Dogs with pre-existing unilateral femoral vein thrombi were anticoagulated with heparin (300 units.kg (-1) bolus followed by 90 units.kg(-1).h(-1) continuous infusion). They were then allocated to receive one of three (111)In labelled antibodies: anti-D-dimer, anti-beta or a non-specific control antibody. Gamma scans of the legs were performed at regular intervals for 24 h. Scans were interpreted in a blinded fashion and the number of gamma counts from the femoral area on the thrombosed side was compared to the contralateral side. Clot/blood isotope density ratios were determined post-mortem.

RESULTS

Leg thrombi were 100% detectable in the anti-D-dimer group, but only 60% detectable in the anti-beta group. Mean +/- SD relative counts in the thrombosed femoral area was 137 +/- 10% compared to the contralateral side in the anti-D-dimer group, but only 116 +/- 20% in the anti-beta group. The clot/blood ratio was 24.5 +/- 2.8 in the anti-D-dimer group, but only 7.8 +/- 2.0 in the anti-beta group.

CONCLUSIONS

In labelled anti-D-dimer provides superior nuclear medicine images of thrombi during intensive anticoagulation compared to anti-beta. Clinical results with radiolabelled anti-D-dimer may be more promising than those previously observed with other anti-fibrin antibodies.

Current status of radionuclide tracer imaging of thrombi and atheroma

The imaging of thrombi and atherosclerotic plaques has great potential for decision making in the management of patients with all types of disease within the circulatory system. This importance is owing to the developments showing that areas of moderate stenosis with underlying atheroma are physiologically reactive and capable of causing reversible clinical symptoms that can progress to irreversible end-organ damage if not effectively treated. Identifying and quantifying areas of smaller vulnerable plaque and areas of acute thrombosis will assist in identification of patients at risk and help determine when and how to treat these patients. Initial efforts in this area used nonspecific constituents of thrombi and atheroma that were radiolabeled using long-lived isotopes, which had high background activity that required imaging over 48 to 72 hours. Newer approaches have focused on the use of small antibody fragments or small peptides, so-called molecular recognition units, that specifically target antigens present only in areas of thrombosis or active atherogenesis. These compounds are labeled Technetium-99 m (99mTc) and provide excellent images. Efforts to image thrombi have been directed at the IIB/IIIA receptor, which is present in low concentration on the cell membrane of circulating quiescent platelets, but on stimulation and active thrombosis, more than 80,000 potential binding sites per platelet appear. One such peptide has been clinically approved for imaging of deep vein thrombophlebitis. Parallel efforts are being made for imaging areas of active atherogenesis by targeting smooth muscle cells and other constituents unique for vulnerable plaques. Efforts in developing these modalities are important to expand the applications to new areas in nuclear cardiology.

Tc-99m HMPAO labeled platelets in the detection of left ventricular thrombosis post acute myocardial infarction

A left ventricular thrombosis post acute myocardial infarction was detected with Tc-99m HMPAO labeled platelet imaging. The left ventricular thrombosis was already detected on early scans, which allowed for a precise diagnosis during the first 6 hours of the study.

Intravascular ultrasound characterization of thrombi of different composition

An in vitro model was designed to test the hypothesis that thrombi of varying composition have different echogenic patterns. Thrombi were prepared in specially designed tubes, mounted on a holder that allows introduction of an intravascular ultrasound catheter rotated inside a subselective sheath. The thrombi were made by the addition of thrombin to whole blood, platelet-rich plasma, and to mixtures of whole blood and platelet-rich plasma with increasing concentration of whole blood relative to the volume of the mixture in the following ratios: 1:5, 2:5, 3:5 and 4:5. Sixty-six thrombi prepared from 11 blood samples of healthy subjects were studied and compared with control tubes filled with saline solution. Platelet-rich thrombi showed low echogenicity similar to saline solution. Whole blood thrombi appeared uniformly "speckled." Mixtures of whole blood and platelet-rich plasma showed a gradual increase in echogenicity with an increasing amount of whole blood in the mixture. Quantitative videodensitometry compared the gray scale intensity of each image relative to background saline. The mean value of echogenicity of platelet-rich thrombi was 0.9 +/- 1.2, and the mean value of whole blood thrombi was 13 +/- 5.3. Platelet-rich thrombi are echo-lucent, and the main echogenic reflectance of thrombi originates from red blood cells. The ultrasound intensity is in linear relation to the amount of red blood cells in the thrombus.

Percutaneous rotational thrombectomy reduces acute reocclusion in an animal model of acute coronary thrombosis

This study was designed to compare acute reocclusion rates after treatment of acute coronary thrombosis with a percutaneous thrombectomy device or standard balloon angioplasty. Our group has previously reported on the rationale and development of a mechanical device for the treatment of intra-arterial thrombosis. This device removes fibrin from thrombus, allowing for dissolution of the cellular elements of the thrombus. Theoretically, thrombus removal (as opposed to displacement) might result in a lower rate of acute rethrombosis. The present study utilizes the device percutaneously in the coronary arteries of closed chest swine and compares recanalization and reocclusion rates with standard balloon angioplasty. Twenty-six animals with total thrombotic coronary occlusions were treated; 13 with each device. Reocclusion rates with the thrombectomy device were significantly reduced at 60 min and 120 min after recanalization (p < 0.02), and the mean time to reocclusion was prolonged by 45 min (p = 0.07). Technical problems included poor handling characteristics in early prototypes and stress fractures secondary to improper use. Changes in catheter design and operator protocols have largely eliminated these problems. We conclude that this study demonstrates the feasibility of percutaneous mechanical thrombectomy in the coronary arteries and that reocclusion rates after recanalization of thrombotic occlusions compare favorably to standard angioplasty.