Distribution and mechanism of uptake of 111InCl3 in a tumor model for lymph node metastases

H4octapa: an acyclic chelator for 111In radiopharmaceuticals

This preliminary investigation of the octadentate acyclic chelator H(4)octapa (N(4)O(4)) with (111)In/(115)In(3+) has demonstrated it to be an improvement on the shortcomings of the current industry "gold standards" DOTA (N(4)O(4)) and DTPA (N(3)O(5)). The ability of H(4)octapa to radiolabel quantitatively (111)InCl(3) at ambient temperature in 10 min with specific activities as high as 2.3 mCi/nmol (97.5% radiochemical yield) is presented. In vitro mouse serum stability assays have demonstrated the (111)In complex of H(4)octapa to have improved stability when compared to DOTA and DTPA over 24 h. Mouse biodistribution studies have shown that the radiometal complex [(111)In(octapa)](-) has exceptionally high in vivo stability over 24 h with improved clearance and stability compared to [(111)In(DOTA)](-), demonstrated by lower uptake in the kidneys, liver, and spleen at 24 h. (1)H/(13)C NMR studies of the [In(octapa)](-) complex revealed a 7-coordinate solution structure, which forms a single isomer and exhibits no observable fluxional behavior at ambient temperature, an improvement to the multiple isomers formed by [In(DTPA)](2-) and [In(DOTA)](-) under the same conditions. Potentiometric titrations have determined the thermodynamic formation constant of the [In(octapa)](-) complex to be log K(ML) = 26.8(1). Through the same set of analyses, the [(111/115)In(decapa)](2-) complex was found to have nonoptimal stability, with H(5)decapa (N(5)O(5)) being more suitable for larger metal ions due to its higher potential denticity (e.g., lanthanides and actinides). Our initial investigations have revealed the acyclic chelator H(4)octapa to be a valuable alternative to the macrocycle DOTA for use with (111)In, and a significant improvement to the acyclic chelator DTPA.

MION-ASF: biokinetics of an MR receptor agent

Receptor-directed MR contrast agents are currently being designed to improve sensitivity and specificity of MR imaging and to provide for functional MR imaging. In the current study we have synthesized a conjugate of asialofetuin (ASF), a bovine plasma protein with a known, high affinity for the hepatic asialoglycoprotein receptor, and a well defined, single crystal superparamagnetic label (monocrystalline iron oxide nanoparticle, MION). MION-ASF is cleared from the circulation more than 300 times faster than MION, has a 3.7 times higher hepatic accumulation, increases liver R2 relaxivity 2.8-fold compared to MION, and accumulates in hepatocytes unlike MION, which accumulates only in macrophages. Competition assays indicate that receptor-mediated hepatocyte uptake can be competitively blocked and that this effect can be demonstrated by imaging. These studies indicate that sensitive iron oxide based probes can be developed for functional MR imaging.