Le Cun Xu scite author profile

Objective. To determine whether overexpression of the high-affinity folate receptor (FR) on activated macrophages can be exploited to selectively target imaging agents to sites of inflammation in rats with adjuvant-induced arthritis (AIA).Methods. Folic acid was conjugated to a 99m Tc chelator (the complex termed EC20), and its distribution was visualized using gamma scintigraphy in healthy rats, rats with AIA, and arthritic rats that had been depleted of macrophages. To confirm that uptake was mediated by the FR, excess folic acid competition studies were conducted, and tissue FR levels were quantitated using a radioligand binding assay. Flow cytometry was also used to investigate uptake of folate conjugates into macrophages of both arthritic and healthy rats.Results. EC20 concentrated in the arthritic extremities of diseased rats but not in the extremities of healthy rats. The intensity of images of affected tissues was greatly reduced in the presence of excess competing folic acid. The livers and spleens of arthritic animals also showed enhanced uptake of EC20 and increased levels of FR. Depletion of macrophages from arthritic animals reduced tissue FR content and concomitantly abolished uptake of EC20. In addition, macrophages isolated from livers of rats with AIA exhibited a significantly higher binding capacity for folate conjugates than did macrophages obtained from healthy rats.Conclusion. Although EC20 is currently undergoing clinical evaluation for use in the imaging of ovarian carcinomas, the present results suggest that it may also be useful for assaying the participation of activated macrophages in inflammatory processes such as rheumatoid arthritis.

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Hydroxamamide as a chelating moiety for the preparation of 99mTc-radiopharmaceuticals III. Characterization of various 99mTc-hydroxamamides

Nakayama¹,

Xu²,

Koga³

et al. 1997

Applied Radiation and Isotopes

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Folate Receptor-β in Activated Macrophages: Ligand Binding and Receptor Recycling Kinetics

et al. 2014

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Activated macrophages overexpress a receptor for the vitamin folic acid termed the folate receptor β (FR-β). Because conjugation of folate to low molecular weight drugs, genes, liposomes, nanoparticles, and imaging agents has minor effects on FR binding, the vitamin can be exploited to target both therapeutic and imaging agents to activated macrophages without promoting their uptake by other healthy cells. In this paper, we characterize the binding, internalization, and recycling kinetics of FR-β on activated macrophages in inflamed tissues of rats with adjuvant-induced arthritis. Our results demonstrate that saturation of macrophage FR is achieved at injection doses of ∼150-300 nmol/kg, with more rapidly perfused tissues saturating at lower doses than inflamed appendages. After binding, FR-β internalizes and recycles back to the cell surface every ∼10-20 min, providing empty receptors for additional folate conjugate uptake. Because the half-life of low molecular weight folate conjugates in the vasculature is usually <1 h, these data suggest that targeting of folate conjugates to activated macrophages in vivo can be maximized by frequent dosing at conjugate concentrations that barely saturate FR (∼150 nmol/kg), thereby minimizing nonspecific binding to receptor-negative tissues and maximizing the probability that unoccupied cell surface receptors will be exposed to folate-drug conjugate.

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Preclinical pharmacokinetics, tissue distribution, and antitumor activity of a folate-hapten conjugate–targeted immunotherapy in hapten-immunized mice

Parker

et al. 2006

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Folic acid (pteroylglutamic acid) represents a useful ligand for targeted cancer therapies because it binds to a common epithelial tumor antigen known as the folate receptor. We previously devised an immunotherapy strategy that uses a bispecific ligand, a folate-hapten (FITC) conjugate, to redirect endogenously induced anti-FITC antibodies to folate receptor -positive tumor cells following parenteral administration. Here, we present results from preclinical pharmacokinetic and tissue biodistribution studies using a radioactive folate-FITC conjugate and results from dose optimization studies done in tumor-bearing animals. Folate-FITC was found to be rapidly eliminated in non-immunized mice; however, in immunized hosts, folate-FITC was shown to form immune complexes with FITC-specific antibodies, the consequence of which was a f173-fold increase in drug exposure (i.e., area under the curve). Using a newly developed ELISA assay, the extent of circulating anti-FITC antibodies occupied by parenterally given folate-FITC was determined to be proportional to the given dose. Furthermore, high doses of folate-FITC were found to promote the cosaturation of tumor cell surface folate receptors and circulating FITC-specific antibodies, blocking the immune recognition of tumor cells and thereby reducing antitumor activity. Nonetheless, by extending the duration of treatment and administering subsaturating doses of folate-FITC, enhanced antitumor response was observed in mice bearing established folate receptor -positive M109 tumors. Overall, results from the present study may help to guide clinicians through on-going clinical investigations of folate-targeted immunotherapy. [Mol Cancer Ther 2006;5(12):3258 -67]

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A universal dual mechanism immunotherapy for the treatment of influenza virus infections

et al. 2020

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Seasonal influenza epidemics lead to 3–5 million severe infections and 290,000–650,000 annual global deaths. With deaths from the 1918 influenza pandemic estimated at >50,000,000 and future pandemics anticipated, the need for a potent influenza treatment is critical. In this study, we design and synthesize a bifunctional small molecule by conjugating the neuraminidase inhibitor, zanamivir, with the highly immunogenic hapten, dinitrophenyl (DNP), which specifically targets the surface of free virus and viral-infected cells. We show that this leads to simultaneous inhibition of virus release, and immune-mediated elimination of both free virus and virus-infected cells. Intranasal or intraperitoneal administration of a single dose of drug to mice infected with 100x MLD50 virus is shown to eradicate advanced infections from representative strains of both influenza A and B viruses. Since treatments of severe infections remain effective up to three days post lethal inoculation, our approach may successfully treat infections refractory to current therapies.

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Le Cun Xu

Folate‐targeted imaging of activated macrophages in rats with adjuvant‐induced arthritis

Hydroxamamide as a chelating moiety for the preparation of 99mTc-radiopharmaceuticals III. Characterization of various 99mTc-hydroxamamides

Folate Receptor-β in Activated Macrophages: Ligand Binding and Receptor Recycling Kinetics

Preclinical pharmacokinetics, tissue distribution, and antitumor activity of a folate-hapten conjugate–targeted immunotherapy in hapten-immunized mice

A universal dual mechanism immunotherapy for the treatment of influenza virus infections

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