This Article Full Text Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Request Permissions Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Narula, J. Articles by Khaw, B.-A. Search for Related Content PubMed PubMed Citation Articles by Narula, J. Articles by Khaw, B.-A. Pubmed/NCBI databases Substance via MeSH

(Circulation. 1995;92:474-484.)
© 1995 American Heart Association, Inc.

Articles

Noninvasive Localization of Experimental Atherosclerotic Lesions With Mouse/Human Chimeric Z2D3 F(ab')₂ Specific for the Proliferating Smooth Muscle Cells of Human Atheroma

Imaging With Conventional and Negative Charge–Modified Antibody Fragments

Presented in part at 1992 (New Orleans, La, November) and 1993 (Atlanta, Ga, November) Scientific Sessions of the American Heart Association.

Jagat Narula, MD, PhD; Artiom Petrov, PhD; Cesario Bianchi, MD, PhD; Charles C. Ditlow, PhD; Bradford C. Lister, PhD; Jeanette Dilley, BS; Isabella Pieslak, BS; Francis W. Chen, PhD; Vladimir P. Torchilin, DSc; Ban-An Khaw, PhD

From Center for Drug Targeting and Analysis (J.N., A.P., B.C.L., B.-A.K.), Northeastern University, Boston, Mass; Massachusetts General Hospital (J.N., C.B., V.P.T., B.-A.K.), Harvard Medical School, Boston, Mass; and Scotgen Biopharmaceuticals Inc (C.C.D., J.D., I.P., F.W.C.), Menlo Park, Calif.

Correspondence to Ban-An Khaw, PhD, George D. Behrakis Professor of Pharmaceutical Sciences, Northeastern University, Director, Center for Drug Targeting and Analysis, Bouvé College of Pharmacy, 205 Mugar Building, 360 Huntington Avenue, Boston, MA 02115.

Background A murine monoclonal antibody designated Z2D3 (IgM) generated against homogenized human atherosclerotic plaques was demonstrated to be highly specific for proliferating smooth muscle cells. The primary clone subsequently was genetically engineered to provide a mouse/human chimeric antibody with human IgG₁ constant region expressed in a rat myeloma cell line. The resulting Z2D3-73.30 chimeric retained the immunoreactivity relative to the parent Z2D3-IgM and was pepsin-digested to yield F(ab')₂. ¹¹¹In-labeled chimeric Z2D3 F(ab')₂ was then used for noninvasive imaging of experimental atherosclerotic lesions. To improve the imaging characteristics, we modified chimeric Z2D3 F(ab')₂ fragments to carry a high negative charge. Improved visualization of targets with ¹¹¹In-labeled, negatively charged, polymer-modified antibodies most probably is the result of faster blood clearance and a decrease in nontarget background activity.

Methods and Results Experimental atherosclerotic lesions were induced in rabbits by deendothelialization of the infradiaphragmatic aorta followed by a 6% peanut oil–2% cholesterol diet. After 12 weeks, localization of the conventionally labeled ¹¹¹In-Z2D3 F(ab')₂ (24 Mbq [650 µCi]/500 to 750 µg) (n=4) was compared with ¹¹¹In-labeled, negatively charged, polymer-modified Z2D3 F(ab')₂ (24 Mbq [650 µCi]/25 to 50 µg) in eight atherosclerotic rabbits. Three control rabbits also received radiolabeled polymer-modified Z2D3. Ten rabbits with atherosclerotic lesions received ¹¹¹In-labeled nonspecific human IgG₁ F(ab')₂ with (n=6) or without (n=4) negative charge modification. Atherosclerotic lesions were visualized in all rabbits with the conventional Z2D3 F(ab')₂ at 48 hours. However, unequivocal lesion visualization was possible at 24 hours only with negatively charged, polymer-modified Z2D3 F(ab')₂. Quantitative uptake of F(ab')₂ fragments was essentially determined by the presence of atherosclerotic lesions (F_1.37=69.8; P<.0001) and the specificity of the antibody (F_1.37=36.6; P<.0001). Uptake of the conventional Z2D3 in atherosclerotic lesions (mean±SEM percent injected dose per gram, 0.112±0.024%) was six times higher than background activity in the normal aortic segments (nondenuded thoracic aorta; mean percent injected dose per gram, 0.019±0.003%). Uptake of the conventional Z2D3 was also significantly higher than that of nonspecific human IgG₁ F(ab')₂ (0.027±0.004%). Specific uptake of the conventional Z2D3 in the lesions was comparable to the charge-modified Z2D3 uptake (0.084±0.017; P=.20). Uptake of negative charge–modified Z2D3 in the lesions was significantly higher than in the corresponding background activity in normal thoracic aorta (0.021±0.002). Uptake of negative charge–modified Z2D3 F(ab')₂ in the lesions was higher than the uptake of negative charge–modified nonspecific IgG₁ F(ab')₂ (0.020±0.002) in the lesions. Uptake of charge-modified Z2D3 in the atherosclerotic lesions was also significantly higher than the corresponding regions of the aorta of the control rabbits (0.017±0.002; F_1.18=27.9; P=.0001). There was, however, no difference in the specific lesion uptake of negative charge–modified Z2D3 at 24 hours (0.079±0.014) and 48 hours (0.084±0.0017; P=.99) after intravenous administration. Nontarget organ activities were lower with negative charge–modified ¹¹¹In-labeled Z2D3 F(ab')₂ than with the conventional Z2D3 F(ab')₂. Mean kidney activity was fourfold less with the modified (0.45±0.06) than with the conventionally radiolabeled (1.67±0.264; P=.001) Z2D3 F(ab')₂.

Conclusions The present study demonstrates the feasibility of noninvasive visualization of experimental atherosclerotic lesions with a mouse/human chimeric antibody Z2D3 F(ab')₂ directed against the proliferating smooth muscle cells. Furthermore, negative charge modification of the chimeric Z2D3 F(ab')₂ enabled (1) earlier visualization of the atherosclerotic lesions, (2) use of 10- to 15-fold less antibody than with conventional Z2D3 F(ab')₂, and (3) reduction of the radiation burden to nontarget organs.

Key Words: atherosclerosis • imaging • angioplasty • antibodies • smooth muscle cells

This article has been cited by other articles:

				M. P. S. Dunphy, H. Schoder, and H. W. Strauss Radionuclide Techniques for Identifying Vulnerable Plaque J. Nucl. Med., November 1, 2007; 48(11): 1753 - 1755. [Full Text] [PDF]

				J. C. Wu, F. M. Bengel, and S. S. Gambhir Cardiovascular Molecular Imaging Radiology, August 1, 2007; 244(2): 337 - 355. [Abstract] [Full Text] [PDF]

				D. R. Elmaleh, A. J. Fischman, A. Tawakol, A. Zhu, T. M. Shoup, U. Hoffmann, A.-L. Brownell, and P. C. Zamecnik Detection of inflamed atherosclerotic lesions with diadenosine-5',5'''-P1,P4-tetraphosphate (Ap4A) and positron-emission tomography PNAS, October 24, 2006; 103(43): 15992 - 15996. [Abstract] [Full Text] [PDF]

				B.-A. Khaw, Y. Tekabe, and L. L. Johnson Imaging Experimental Atherosclerotic Lesions in ApoE Knockout Mice: Enhanced Targeting with Z2D3-Anti-DTPA Bispecific Antibody and 99mTc-Labeled Negatively Charged Polymers J. Nucl. Med., May 1, 2006; 47(5): 868 - 876. [Abstract] [Full Text] [PDF]

				J. Jimenez, T. Donahay, L. Schofield, B. A. Khaw, and L. L. Johnson Smooth Muscle Cell Proliferation Index Correlates with 111In-Labeled Antibody Z2D3 Uptake in a Transplant Vasculopathy Swine Model J. Nucl. Med., March 1, 2005; 46(3): 514 - 519. [Abstract] [Full Text] [PDF]

				J. R. Davies, J. H. Rudd, and P. L. Weissberg Molecular and Metabolic Imaging of Atherosclerosis J. Nucl. Med., November 1, 2004; 45(11): 1898 - 1907. [Abstract] [Full Text] [PDF]

				L. L. Johnson, L. M. Schofield, D. K. Weber, F. Kolodgie, R. Virmani, and B. A. Khaw Uptake of 111In-Z2D3 on SPECT Imaging in a Swine Model of Coronary Stent Restenosis Correlated with Cell Proliferation J. Nucl. Med., February 1, 2004; 45(2): 294 - 299. [Abstract] [Full Text] [PDF]

				J. J. Bax and P. V. Oemrawsingh Can Molecular Imaging Predict In-Stent Restenosis? J. Nucl. Med., February 1, 2004; 45(2): 300 - 301. [Full Text] [PDF]

				K. Ohtsuki, M. Hayase, K. Akashi, S. Kopiwoda, and H. W. Strauss Detection of Monocyte Chemoattractant Protein-1 Receptor Expression in Experimental Atherosclerotic Lesions: An Autoradiographic Study Circulation, July 10, 2001; 104(2): 203 - 208. [Abstract] [Full Text] [PDF]

				G. Pasterkamp, E. Falk, H. Woutman, and C. Borst Techniques characterizing the coronary atherosclerotic plaque: influence on clinical decision making? J. Am. Coll. Cardiol., July 1, 2000; 36(1): 13 - 21. [Abstract] [Full Text] [PDF]

				G. A. Beller and B. L. Zaret Contributions of Nuclear Cardiology to Diagnosis and Prognosis of Patients With Coronary Artery Disease Circulation, March 28, 2000; 101(12): 1465 - 1478. [Full Text] [PDF]

				D. R. Elmaleh, J. Narula, J. W. Babich, A. Petrov, A. J. Fischman, B.-A. Khaw, E. Rapaport, and P. C. Zamecnik Rapid noninvasive detection of experimental atherosclerotic lesions with novel 99mTc-labeled diadenosine tetraphosphates PNAS, January 20, 1998; 95(2): 691 - 695. [Abstract] [Full Text] [PDF]