Hematopoietic growth factors pass through the blood-brain barrier in intact rats.

We have previously demonstrated that receptors for hematopoietic growth factors, stem cell factor (SCF) and granulocyte-colony stimulating factor (G-CSF) are expressed in the neurons and the neural progenitor cells (NPCs) of the adult rat brain, and that systemic administration of SCF and G-CSF in the first week after induction of cortical brain ischemia (3 h-7 days post-ischemia) significantly improves functional outcome, augments NPC proliferation, and reduces infarct volume in rats. The purpose of the present study is to determine whether SCF and G-CSF pass through the blood-brain barrier (BBB) in intact rats. The growth factors were labeled with iodine (I(125)), a radioactive compound. I(125)-SCF and I(125)-G-CSF were intravenously administered and the concentrations of I(125)-SCF and I(125)-G-CSF in the blood plasma and the brain were determined at 10, 30, 60, and 120 min after injection. We observed that both SCF and G-CSF were slowly and continuously transported from the blood stream to the brain in the same rate. In addition, both immunofluorescent staining and Western blots showed that receptors for SCF and G-CSF were expressed in the capillaries of the adult rat brain, suggesting that SCF and G-CSF entry to the brain may be mediated via receptor-mediated transport, one of the endogenous transports in the BBB. These data indicate that both SCF and G-CSF were able to pass through the BBB in intact animals. This observation will help in further exploring the physiological role of peripheral SCF and G-CSF in the brain and therapeutic possibility to chronic stroke.

Efflux of drugs and solutes from brain: the interactive roles of diffusional transcapillary transport, bulk flow and capillary transporters.

We examined the roles of diffusion, convection and capillary transporters in solute removal from extracellular space (ECS) of the brain. Radiolabeled solutes (eight with passive distribution and four with capillary or cell transporters) were injected into the brains of rats (n=497) and multiple-time point experiments measured the amount remaining in brain as a function of time. For passively distributed compounds, there was a relationship between lipid:water solubility and total brain efflux:diffusional efflux, which dominated when k(p), the transcapillary efflux rate constant, was >10(0) h(-1); when 10(-1)

Therapeutic implications of tumor interstitial fluid pressure in subcutaneous RG-2 tumors.

Increased interstitial fluid pressure (IFP) in brain tumors results in rapid removal of drugs from tumor extracellular space. We studied the effects of dexamethasone and hypothermia on IFP in s.c. RG-2 rat gliomas, because they could potentially be useful as means of maintaining drug concentrations in human brain tumors. We used dexamethasone, external hypothermia, combined dexamethasone and hypothermia, and infusions of room temperature saline versus chilled saline. We measured tumor IFP and efflux half-time of 14C-sucrose from tumors. In untreated s.c. tumors, IFP was 9.1 +/- 2.1 mmHg, tumor temperature was 33.7 degrees C +/- 0.7 degrees C, and efflux half-time was 7.3 +/- 0.7 min. Externally induced hypothermia decreased tumor temperature to 8.9 degrees C +/- 2.9 degrees C, tumor IFP decreased to 3.2 +/- 1.1 mmHg, and efflux half-time increased to 13.5 min. Dexamethasone decreased IFP to 2.4 +/- 1.0 mmHg and increased efflux half-time to 15.4 min. Combined hypothermia and dexamethasone further increased the efflux half-time to 17.6 min. We tried to lower the tumor temperature by chilling the infusion solution, but at an infusion rate of 48 mul/min, the efflux rate was the same for room temperature saline and 15 degrees C saline. The efflux rate was increased in both infusion groups, which suggests that efflux due to tumor IFP and that of the infusate were additive. Since lowering tumor IFP decreases efflux from brain tumors, it provides a means to increase drug residence time, which in turn increases the time-concentration exposure product of therapeutic drug available to tumor.

Isolation of drug delivery from drug effect: problems of optimizing drug delivery parameters.

A recurring question in the treatment of malignant brain tumors has been whether treatment failure is due to inadequate delivery or ineffective drugs. To isolate these issues, we tested a paradigm in which the "therapeutic" agent was a toxin about which there could be no question of efficacy, provided it was delivered in adequate amounts; we used 10% formalin. We infused 10% formalin into 5- to 8-mm subcutaneous RG-2 and D54-MG gliomas at increasing rates until we achieved 100% tumor cell kill. In RG-2 gliomas, infusions of 10 microl/h x 7 days, and 2, 4, 6, and 8 microl/min x 2 h failed to kill tumors, although growth was delayed, while infusion rates of 12 microl/min x 60 min and 48 microl/min x 15 min produced 100% tumor kill. In D54-MG tumors, infusions of 4, 8, and 24 microl/min produced 100% tumor kill. 14C-Formalin autoradiographs showed a heterogeneous distribution after infusions of 2 microl/min x 2 h, whereas infusions of 48 microl/min x 15 min showed a homogeneous distribution within the tumor, but more than 95% of tissue radioactivity was found in tissue surrounding tumor. Drug delivery remains a major issue in brain tumor treatment: Distribution inhomogeneity, rapid efflux, and consequent treatment failures are likely due to high interstitial fluid pressure. Because the infusion rates being used in the treatment of human brain tumors are low and the tumors are larger, treatment failures can be expected on the basis of inadequate drug delivery alone, regardless of the effectiveness of the drug.

Comparative pharmacokinetics of 14C-sucrose in RG-2 rat gliomas after intravenous and convection-enhanced delivery.

We compared tissue and plasma pharmacokinetics of 14C-sucrose in subcutaneous RG-2 rat gliomas after administration by 3 routes, intravenous bolus (i.v.-B; 50 microCi over 30 s), continuous i.v. infusion (i.v.-C, 50 microCi at a constant rate), and convection-enhanced delivery (CED, 5 microCi infused at a rate of 0.5 microl/min), and for 3 experimental durations, 0.5, 2, and 4 h. Plasma, tumor, and other tissue samples were obtained to measure tissue radioactivity. Plasma radioactivity in the CED group increased exponentially and lagged only slightly behind the IV-C group. After 90 min, plasma values were similar in all. Mean tumor radioactivity was 100 to 500 times higher in the CED group at each time point than in the i.v.-B and i.v.-C groups. Tumor radioactivity was homogeneous in the i.v. groups at 0.5 h and inhomogeneous at 1 and 2 h. In CED, radioactivity distribution was inhomogeneous at all 3 time points; highest concentrations were in tissue around tumor and in necrosis, while viable tumor contained the lowest and sometimes negligible amounts of isotope. Systemic tissue radioactivity values were similar in all groups. Efflux of 14C-sucrose from tumors was evaluated in intracerebral tumors (at 0.5, 1, 2, and 4 h) and subcutaneous tumors (at 0 to 0.5 h). Less than 5% of 14C activity remained in intracerebral tumors at each time point. The efflux half-time from the subcutaneous tumors was 7.3 +/- 0.7 min. These results indicate rapid efflux of drug from brain tumor and marked heterogeneity of drug distribution within tumor after CED administration, both of which may be potentially limiting factors in drug delivery by this method.