Technetium-99m labelled LDL as a tracer for quantitative LDL scintigraphy

The goal of the present study was to optimize technetium-99m labelling of low-density lipoprotein (LDL) and to investigate the in vitro and in vivo properties of the tracer to determine whether its application for quantitative scintigraphy of hepatic LDL receptor activity is feasible. LDL labelled with iodine-125 by the iodine monochloride method was used as a reference tracer. Comparison of different assessments of radiochemical purity [trichloro-acetic acid precipitation (%ppTCA), paper chromatography, size-exclusion chromatography and chloroform-methanol extraction] exhibited %ppTCA to be superior as a parameter of tracer quality. In spite of a high radiochemical purity immediately after labelling, modifications of 99mTc labelling of LDL did not overcome the poor long-term stability of the tracer. Subsequent dialysis in phosphate buffer over about 3 h sufficiently increased the long-term stability in vitro and in vivo. The competitive recognition of dialysed 99mTc-LDL and 125I-LDL with native LDL by high-affinity binding sites was demonstrated in human hepatoma cells (HepG2) and human fibroblasts. Biodistribution data of simultaneously injected 99mTc-LDL and 125I-LDL in New Zealand White rabbits showed a high uptake of both tracers in tissues with high LDL receptor activity, yet 99mTc-LDL uptake exceeded lzSI-LDL uptake by two-to sevenfold. In contrast to 125I-LDL, 99mTc-LDL showed a higher unspecific uptake into the bone marrow and the spleen, suggesting an additional uptake mechanism probably via the scavenger pathway. Curve deconvolution of plasma clearance in five female New Zealand White rabbits and five male hyperlipidaemic patients again showed a marginally different biokinetic behaviour of 99mTc-LDL and lzSI-LDL. It is concluded that dialysis