Reticuloendothelial stimulation: levamisole compared

Age-dependent differences in the efficacy of cancer immunotherapy in C57BL and AKR mouse strains

While tumor incidence increases with age, tumor growth and metastasis often proceed at a slower rate in aged organisms. The mechanisms underlying this age-related reduced tumor development may suggest therapeutic modalities appropriate for the aged. Decreased tumor aggressiveness in the old was shown to be related to altered immune response. Consequently, the aim of the present study was to assess whether cancer immunotherapy has an age-dependent effect. Only a few studies have compared cancer immunotherapy efficiency as a function of age, most showing lower inhibition in older animals. In the present study, we tested the effect of two immunomodulators, levamisole and BCG, on two tumors, B16 melanoma and AKR lymphoma, in mice of different ages. We demonstrated a higher efficiency of immunotherapy in aged as compared to young mice, particularly at low immunomodulator doses. While decreased T cell function during aging is apparently established, nonspecific immunity is more preserved or even enhanced in later life. We found an increased number of macrophages in tumors of old compared to young mice and an increase in MAC-1+ cells in old levamisole-treated compared to non-treated mice. The stronger therapeutic effect of this immunomodulator in old mice might thus be due to an increased macrophage-mediated anti-tumoral effect.

Effects of octreotide on liver regeneration and tumour growth in the regenerating liver

The ability of the liver to regenerate following resection is remarkable. However, there is evidence to suggest that tumour growth within the regenerating liver is significantly increased. As octreotide (a synthetic analogue of somatostatin) inhibits the growth and development of hepatic tumour in rats, we have investigated its effects on liver regeneration, liver blood flow, hepatic reticuloendothelial system activity and tumour growth in the rat following partial hepatectomy (PH). Octreotide significantly inhibited liver regeneration in the rat 1 and 2 weeks following PH when compared with controls (regeneration index: 1.0 and 1.14 cf. 1.14 and 1.4, respectively). There was no significant difference in hepatic arterial or portal venous blood flow following PH in control or octreotide-treated rats. However, portal pressure was significantly reduced in octreotide-treated rats. Hepatic reticuloendothelial system activity was significantly increased in octreotide-treated rats compared with control animals 1 and 2 weeks after hepatectomy (uptake of radiolabelled technetium-99m albumin colloid: 2.2 and 3.9 cf. 1.6 and 1.9). The growth of both HSN (fibrosarcoma) and K12-Tr (colonic adenocarcinoma) cells in the regenerating liver was significantly decreased by octreotide treatment compared with controls (median percentage hepatic replacement: HSN control 71.3%, Octreotide 8.4%, K12-Tr Control 38.3%, Octreotide 4.5%). The results of the present study demonstrate that octreotide inhibits both liver regeneration and tumour growth following PH, possibly via a similar mechanism.

Octreotide inhibits the growth and development of three types of experimental liver metastases

A study was performed to assess the effects of octreotide on the growth and development of liver metastases in rats. Tumour was induced by intraportal injection of three tumorigenic cell lines (the fibrosarcoma HSN and colonic adenocarcinomas K12/Tr and WB2054M) in syngeneic rats. Octreotide treatment (2 micrograms subcutaneously for 3 or 4 weeks) was started 18 h and 1 week after tumour induction; a delay in treatment of 1 week allowed micrometastases to develop. Treatment with octreotide significantly (P < 0.001) reduced the median hepatic replacement of liver by tumour compared with that of control rats given saline (controls: HSN 76.4 per cent, K12/Tr 17.5 per cent, WB2054M 43.9 per cent; octreotide treatment delayed 18 h: HSN 2.7 per cent, K12/Tr 0.6 per cent, WB2054M 1.3 per cent; octreotide treatment delayed 1 week: HSN 9.3 per cent, K12/Tr 2.5 per cent, WB2054M 2.3 per cent). These results clearly indicate that octreotide significantly inhibits the growth and development of experimental liver metastases. Further studies are required both to delineate the mechanism of action and to investigate these effects in a clinical setting.

Octreotide, the reticuloendothelial system, and experimental liver tumour

The inhibitory effect of octreotide on the growth of liver tumour is probably mediated (at least in part) by stimulation of the hepatic reticuloendothelial system (RES) activity. This study therefore investigated the effect of octreotide on the hepatic and splenic RES (assessed by the uptake of technetium 99m labelled albumin colloid, 99mTc-AC) in normal and tumour bearing rats and in animals treated with gadolinium chloride. The effects of gadolinium chloride and octreotide alone or in combination on the growth of liver tumour were also studied. Octreotide significantly stimulates both hepatic and splenic uptake of 99mTc-AC in normal rats and tumour bearing rats. In controls, the uptake of 99mTc-AC was significantly reduced by gadolinium chloride and was not changed by octreotide. RES blockade with gadolinium chloride significantly increased (p < 0.001) tumour growth compared with controls (hepatic replacement 42%; 95% confidence intervals (CI), 27.6 to 56.4 v 16.7%, 95% CI, 11.1 to 21.3%) whereas octreotide significantly inhibited (p < 0.001) the percentage hepatic replacement by tumour (0.7%; 95% CI, 0 to 2.3 v 16.7%; 95% CI, 11.1 to 21.3). This study highlights the importance of the RES in the development of liver tumour. Furthermore, octreotide inhibited the growth of liver tumour in rats with RES blockade, albeit to a lesser degree than in normal animals. These findings suggest that octreotide inhibits the growth of hepatic tumour by mechanisms other than stimulation of RES activity.