Multimodal and Multiscale Analysis Reveals Distinct Vascular, Metabolic and Inflammatory Components of the Tissue Response to Limb Ischemia.

Ischemia triggers a complex tissue response involving vascular, metabolic and inflammatory changes. METHODS: We combined hybrid SPECT/CT or PET/CT nuclear imaging studies of perfusion, metabolism and inflammation with multicolor flow cytometry-based cell population analysis to comprehensively analyze the ischemic tissue response and to elucidate the cellular substrate of noninvasive molecular imaging techniques in a mouse model of hind limb ischemia. RESULTS: Comparative analysis of tissue perfusion with [99mTc]-Sestamibi and arterial influx with [99mTc]-labeled albumin microspheres by SPECT/CT revealed a distinct pattern of response to vascular occlusion: an early ischemic period of matched suppression of tissue perfusion and arterial influx, a subacute ischemic period of normalized arterial influx but impaired tissue perfusion, and a protracted post-ischemic period of hyperdynamic arterial and normalized tissue perfusion, indicating coordination of macrovascular and microvascular responses. In addition, the subacute period showed increased glucose uptake by [18F]-FDG PET/CT scanning as the metabolic response of viable tissue to hypoperfusion. This was associated with robust macrophage infiltration by flow cytometry, and glucose uptake studies identified macrophages as major contributors to glucose utilization in ischemic tissue. Furthermore, imaging with the TSPO ligand [18F]-GE180 showed a peaked response during the subacute phase due to preferential labeling of monocytes and macrophages, while imaging with [68Ga]-RGD, an integrin ligand, showed prolonged post-ischemic upregulation, which was attributed to labeling of macrophages and endothelial cells by flow cytometry. CONCLUSION: Combined nuclear imaging and cell population analysis reveals distinct components of the ischemic tissue response and associated cell subsets, which could be targeted for therapeutic interventions.

Effective cancer therapy with the alpha-particle emitter [211At]astatine in a mouse model of genetically modified sodium/iodide symporter-expressing tumors.

PURPOSE: The sodium/iodide symporter (NIS) gene is currently explored in several trials to eradicate experimental cancer with radiodine ((131)I) by its beta-emission. We recently characterized NIS-specific cellular uptake of an alternative halide, radioastatine ((211)At), which emits high-energy alpha-particles. The aim of this study was to investigate in vivo effects of the high linear energy transfer (LET) emitter (211)At on tumor growth and outcome in nude mice. EXPERIMENTAL DESIGN: We administered radioastatide in a fractionated therapy scheme to NMRI nude mice harboring rapidly growing solid tumors established from a papillary thyroid carcinoma cell line genetically modified to express NIS (K1-NIS). Animals were observed over 1 year. Tumor growth, body weight, blood counts, survival, and side effects were measured compared with control groups without therapy and/or lack of NIS expression. RESULTS: Within 3 months, radioastatide caused complete primary tumor eradication in all cases of K1-NIS tumor-bearing nude mice (n = 25) with no tumor recurrence during 1 year follow-up. Survival rates of the K1-NIS/(211)At group were 96% after 6 months and 60% after 1 year, in contrast to those of control groups (maximum survival 40 days). CONCLUSION: Our study indicates that (211)At represents a promising substrate for NIS-mediated therapy of various cancers either with endogenous or gene transfer-mediated NIS expression.

Cerebral hypoperfusion and delayed hippocampal response after induction of adult kaolin hydrocephalus.

BACKGROUND AND PURPOSE: In chronic hydrocephalus, a role for tissue hypoxia resulting from cerebrovascular compression is suggested. The purpose of this study was to evaluate whether changes in cerebral blood flow (CBF) in the time course of adult kaolin-induced hydrocephalus correlated with immunohistochemical neuronal responses. METHODS: In 46 adult Sprague-Dawley rats, kaolin hydrocephalus was induced and immunostaining of neurofilament protein (NF68), synaptophysin (SYN38), and neuronal nitric oxide synthase (NOS) was performed at 2 (short term), 4 (intermediate term), and 6 and 8 (long term) weeks. Local CBF was measured quantitatively by [14C]iodoantipyrine ([14C]IAP) autoradiography in the short-term stage and in both long-term stages. RESULTS: At 2 weeks, neuronal NOS immunoreactivity was globally increased in cortical areas and within the hippocampus. Four weeks after hydrocephalus induction, a reactive increase of SYN38 and NF68 immunoreactivity in the periventricular cortex was seen. At 6 and 8 weeks, when the ventricular size was decreasing, immunohistochemical changes in the hippocampus became most evident. A maintained toxic NOS reactivity in the CA1 subfield was accompanied by a loss of NF68 staining. In the CA3 subfield, however, focal increases in NF68 and SYN38 immunoreactivity were found. Cortical and hippocampal blood flow showed prolonged decreases of 25% to 55% compared with control animals. At 8 weeks, control levels were reached. CONCLUSIONS: The observed temporary CBF decrease appears to correlate with an early global neuronal ischemic response. In addition, it may also account for the delayed selective response of ischemia-vulnerable structures, eg, hippocampus, in chronic adult kaolin-induced hydrocephalus.