Nuclear imaging is an established clinical molecular imaging modality that offers good sensitivity deep in tissue. However, nuclear imaging is limited by several factors such as timeconsuming data acquisition, expensive equipment, exposure to radioactivity, the need for highly skilled personnel, and relatively poor spatial resolution. 1 Optical imaging is a relatively new imaging modality that offers real-time, non-radioactive, and, depending on the technique, high-resolution imaging of fluorophores embedded in diseased tissues. 2 Of the various optical imaging techniques investigated to date, near-infrared (NIR, 700−900 nm wavelength) fluorescence-based imaging is of particular interest for noninvasive in vivo imaging because of the relatively low tissue absorption, scatter, and minimal autofluorescence of NIR light. 3 NIR fluorescence has the potential to provide rapid, inexpensive, and non-radioactive population-based screening for breast cancer. 4-6 However, it is unclear whether currently available optical imaging systems have adequate sensitivity and/or resolution to identify breast pathology such as microcalcifications. In this study, we developed a critical reagent for exploring the limits of NIR fluorescence-based breast cancer diagnosis, namely, a simultaneous optical and nuclear contrast agent.Bisphosphonates (BPs) bind avidly to hydroxyapatite (HA) bone mineral surfaces, 7 and have many uses. BP-based radiotracers are used to diagnose osteoblastic bone lesions and to treat bone metastasis associated with breast cancer. 8 In addition, contrast agents (CAs) with BPs and phosphonates as the targeting group have been developed for use with nuclear imaging. 9, 10 Although, our group 11-13 and others 14 have explored NIR imaging with BPs, to the best of our knowledge, no BP-based dual modality nuclear-NIR contrast agents have been reported. Dual-labeled targeting imaging agents, such as the one described herein, allow cross validation and direct comparison between nuclear (the gold-standard) and fluorescence optical imaging.The tri-functional diagnostic agent Pam-Tc/Re-800 was synthesized in 5 chemical steps (Scheme 1), with an overall yield of 53%, from N-ε-t.-Boc-L-lysine 1, Me-Pam, 13 MAS 3 , and IRDye800CW. Primary amine of compound 1 was conjugated with N-hydroxy succinimide ester of IRDye800CW to obtain Lys(t.-Boc)-800CW-carboxylic acid 2. Me-Pam reacted with activated compound 2 in presence of HCTU and NMM to generate Lys(t.-Boc)-800CW-PamMe 3. Compound 3 was treated with trifluoroacetic acid and trimethylsilyl bromide to deprotect E-mail: jfrangio@bidmc.harvard.edu. Supporting Information Available: Experimental procedures and spectroscopic data. This material is available free of charge via the Internet at http://pubs.acs.org. Pam-Tc/Re-800 6 was fully characterized for its radioactivity, spectral properties (Supporting Information), and calcium salt specificity (Figure 1). Specific activity of Pam-Tc-800 6a was greater than or equal to 6,250 Ci/mmol and radiochemical purity was greater than or eq...
