The cyclosporin PSC 833 increases survival and delays engraftment of human multidrug-resistant leukemia cells in xenotransplanted NOD-SCID mice.

Circumvention of chemoresistance in cancer may involve several modulator drugs with high affinity for the multidrug transporter P-glycoprotein (Pgp), which is expressed in a number of multi-resistant malignancies. Pgp acts as a membrane efflux pump with broad substrate specificity including antineoplastic drugs and endogenous substances such as certain cytokines and sphingolipids. Therefore, the consequence of Pgp blockade could be far more complex than intracellular drug retention. In the present study exposure of the Pgp inhibitor, PSC 833 (1200 ng/ml), to Pgp expressing KG1a/200 human leukemia cells provoked cell cycle arrest and apoptosis in vitro. This finding was put to test in vivo using a xenotransplant model of KG1a/200 human cells intravenously inoculated into non-obese diabetic severe combined immunodeficient (NOD-SCID) mice. The animals were randomly allocated to receive treatment with PSC 833 (n = 32) or placebo (n = 24). PSC 833 (30 mg/kg) was subcutaneously injected six or 12 times separated by 48-96 h. The overall mean whole blood concentration of PSC 833 was 1191 +/- 60 ng/ml (s.e.m.) at 20 h after administration. Tumor engraftment was significantly reduced in the treatment group (P = 0.037), which also had prolonged survival compared to control animals (P = 0.0016). This is the first study that demonstrates antileukemic effects of a Pgp inhibitor as single agent therapy in vivo, and the present data raise the possibility of alternative exploitation of modulators in cancer chemotherapy.

Inhibitors of angiogenesis selectively reduce the malignant cell load in rodent models of human myeloid leukemias.

Angiogenesis is essential for growth and metastasis of solid tumors and probably also for hematological malignancies. Angiogenic inhibitors, like endostatin (ES) and PI-88, retard cancer growth. We tested these in mice with juvenile myelomonocytic leukemia (JMML), and in rats with acute myeloid leukemia (BNML). Eight weeks after transplantation and with a continuous drug treatment for the last 4 weeks, the leukemic cell mass decreased from almost 90% of all bone marrow cells to about 15 and 45% with ES, to about 35 and 55% with PI-88, and to about 10 and 25% with ES + PI-88 in the leukemic mice and rats, respectively. The numbers of normal human bone marrow cells transplanted into mice were unchanged by the treatments. The microvessel density in leukemic animals given ES or PI-88 was 10-50% of that in untreated animals. Notably, simultaneous treatment with ES and PI-88 led to a reduction of about 95% in JMML mice and 85% in BNML rats. In vitro proliferation of either JMML or BNML cells was not significantly altered by either drug, demonstrating the selectivity of ES and PI-88 as angiogenic inhibitors. In conclusion, anti-angiogenic therapy may be a valuable adjunct to conventional treatment of leukemia.

Local endostatin treatment of gliomas administered by microencapsulated producer cells.

We describe a technique for the treatment of malignant brain tumors based on local delivery of the anti-angiogenic protein endostatin from genetically engineered cells encapsulated in ultrapure sodium alginate. Alginate consists of L-guluronic and D-mannuronic acid, which in the presence of divalent cations forms an extended gel network, in which cells reside and remain immunoisolated, when implanted into the rat brain. Here, we show that endostatin-transfected cells encapsulated in alginate maintain endostatin secretion for at least four months after intracerebral implantation in rats. During the implantation period 70% of the encapsulated cells remained viable, as opposed to 85% in in vitro-cultured capsules. Rats that received transplants of BT4C glioma cells, together with endostatin-producing capsules (0.2 microg/ml per capsule), survived 84% longer than the controls. The endostatin released from the capsules led to an induction of apoptosis, hypoxia, and large necrotic avascular areas within 77% of the treated tumors, whereas all the controls were negative. The encapsulation technique may be used for many different cell lines engineered to potentially interfere with the complex microenvironment in which tumor and normal cells reside. The present work may thus provide the basis for new therapeutic approaches toward brain tumors.

Reproductive function in male rats after brief in utero exposure to diethylstilboestrol.

Long-term effects of brief in utero exposure to diethylstilboestrol (DES) during a foetal period known to be critical for gonadal development were evaluated. Rats were exposed to DES (100 microg/kg body-weight) from day 17 to 19 of pregnancy. All of the DES-treated pregnant rats (11/11) ate parts or whole of their offspring during the first day after birth (p=0.03). Surviving male offspring were examined on day 63 post-partum. DES induced a reduction in weight of the testis (p=0.06) and ventral prostate (p=0.07), even after this short exposure. DES tended to reduce the number of Sertoli cells (p=0.13). Our findings indicate that even a short in utero exposure of rats to DES during a critical period for gonadal development results in cannibalism and reduced testis and ventral prostate weight.

A nuclease-resistant protein kinase C alpha ribozyme blocks glioma cell growth.

We investigated the cleavage activity, stability, and efficacy of 2'-amino pyrimidine modified ribozymes on malignant glioma growth. A synthetic protein kinase C alpha (PKC alpha) ribozyme with complete pyrimidine nucleotide substitution retained a comparable cleavage activity compared with the unmodified ribozyme. The half-life of the modified ribozyme in serum was increased 14,000-fold compared with the unmodified version. The PKC alpha modified ribozyme inhibited glioma cell growth in vitro as a result of the inhibition of PKC alpha gene expression. A single injection of cationic liposome ribozyme complexes into glioma tumors inhibited tumor growth, demonstrating both the efficacy of the ribozyme and a major role of PKC alpha in tumor growth.

Lidocaine pharmacokinetics and toxicity in newborn pigs.

In newborn infants suffering from perinatal asphyxia seizures, lidocaine (LD) has proved to be an effective anticonvulsant. At high concentrations, however, LD can itself cause convulsions. The convulsive concentration of LD (LD(conv)) varies among species. The aim of this study was to describe LD pharmacokinetics and to define the LD(conv) in awake newborn pigs. Eighteen Land race newborn pigs aged 12-60 h, weight 1.0-2.5 kg, were enrolled. LD, 2 mg/kg intravenous (IV) bolus, (n = 11) was given to estimate pharmacokinetic variables. Continuous LD infusion 2 mg x kg(-1) x min(-1) IV (n = 5) and repeated bolus doses of 15 mg/kg (n = 4) were given until electroencephalogram-confirmed seizures appeared. After the bolus injection, the elimination half-life for LD was 0.87-5.44 h. Increasing plasma concentration (LD(pl)) during infusion resulted in sedation after 5-10 min and in shivering, nystagmus, neck extension, tonic-clonic seizures at LD(conv) of 40.6 +/- 12.7 mg/L (mean +/- SD). The unbound LD(pl) at seizures was 4.4 +/- 2.4 mg/L. Younger animals convulsed at higher LD(conv) (r2 = 0.85). LD pharmacokinetics in newborn pigs were found to be dose-dependent at high plasma concentrations. At lower plasma concentrations, LD pharmacokinetics appeared to be linear. The central nervous system is the primary target for the toxic effect of LD in awake newborn pigs. LD neurotoxicity is age-dependent, and younger pigs convulse at a higher LD(conv).

Immobilization of Norwegian reindeer (Rangifer tarandus tarandus) and Svalbard Reindeer (R. t. platyrhynchus) with medetomidine and medetomidine-ketamine and reversal of immobilization with atipamezole.

The sedative action of medetomidine (-ketamine) was studied in 12 captive Norwegian semidomesticated reindeer (NR), including 4 newborn calves, and in 7 free-living Svalbard reindeer (SR). Medetomidine, with or without ketamine, caused effective, reliable immobilization in NR. Doses of 50-200 micrograms/kg medetomidine alone or 30-125 micrograms/kg medetomidine combined with greater than or equal to 300 micrograms/kg ketamine induced complete immobilization, good muscle relaxation and persistent, deep sedation with little respiratory depression in NR; SR required higher doses. Atipamezole successfully antagonized medetomidine (-ketamine) resulting in rapid and persistent reversal of immobilization in all cases (NR and SR). Both medetomidine and atipamezole had wide safety margins and no conspicuous lasting side effects after reversal.