Losartan versus enalapril on cerebral edema and proteinuria in stroke-prone hypertensive rats

Stroke-prone spontaneously hypertensive rats (SHRSP), subjected to high NaCl, show severe hypertension, organ damage, and early death. Preventive treatment with angiotensin II type 1 (AT1) receptor antagonists is known to be effective. Previously, we found that angiotensin converting enzyme (ACE) inhibition could reduce cerebral edema when treatment was started after manifestation of either proteinuria or cerebral edema. In this study AT1 receptor blockade was started at the same time points to evaluate whether this had an effect superior to ACE inhibition. SHRSP drank 1% NaCl. Group 1 served as controls. Group 2 and 3 rats were started on losartan and enalapril after proteinuria exceeded 40 mg/day. Group 4 and 5 rats were started on losartan and enalapril after the first observation of cerebral edema with T2-weighted magnetic resonance imaging scans. In controls, median survival was 54 days (range, 35 to 80 days) after the start of salt loading. With early-onset losartan and enalapril, survival increased to 305 days (range, 184 to 422 days) and 320 days (range, 134 to 368 days) (both P <.01 v group 1). Cerebral edema formation was prevented in all but two rats, one from each treatment modality. Development of proteinuria was markedly reduced. With late-onset treatment with losartan and enalapril, survival was 290 days (range, 120 to 367 days) and 264 days (range, 154 to 319 days) (both P <.01). Both losartan and enalapril decreased cerebral edema to baseline levels. Ultimately cerebral edema reoccurred, despite continued treatment, in 75% of the rats. Systolic blood pressure did not decrease after losartan treatment, but, similarly to early-onset treatment, decreased transiently after enalapril treatment. Cerebral edema and proteinuria were prevented and reduced in SHRSP treated with either an AT1 receptor antagonist or an ACE inhibitor. Survival was markedly and similarly prolonged by both treatments, whether initiated directly before or after development of cerebral edema. In rats where treatment was initiated after manifestation of cerebral edema, both cerebral edema and proteinuria reappeared despite continued treatment. Apparently, when hypertension is sustained, reappearance of target organ damage may not be entirely dependent on angiotensin

Losartan versus enalapril on cerebral edema and proteinuria in stroke-prone hypertensive rats

Stroke-prone spontaneously hypertensive rats (SHRSP), subjected to high NaCl, show severe hypertension, organ damage, and early death. Preventive treatment with angiotensin II type 1 (AT1) receptor antagonists is known to be effective. Previously, we found that angiotensin converting enzyme (ACE) inhibition could reduce cerebral edema when treatment was started after manifestation of either proteinuria or cerebral edema. In this study AT1 receptor blockade was started at the same time points to evaluate whether this had an effect superior to ACE inhibition. SHRSP drank 1% NaCl. Group 1 served as controls. Group 2 and 3 rats were started on losartan and enalapril after proteinuria exceeded 40 mg/day. Group 4 and 5 rats were started on losartan and enalapril after the first observation of cerebral edema with T2-weighted magnetic resonance imaging scans. In controls, median survival was 54 days (range, 35 to 80 days) after the start of salt loading. With early-onset losartan and enalapril, survival increased to 305 days (range, 184 to 422 days) and 320 days (range, 134 to 368 days) (both P <.01 v group 1). Cerebral edema formation was prevented in all but two rats, one from each treatment modality. Development of proteinuria was markedly reduced. With late-onset treatment with losartan and enalapril, survival was 290 days (range, 120 to 367 days) and 264 days (range, 154 to 319 days) (both P <.01). Both losartan and enalapril decreased cerebral edema to baseline levels. Ultimately cerebral edema reoccurred, despite continued treatment, in 75% of the rats. Systolic blood pressure did not decrease after losartan treatment, but, similarly to early-onset treatment, decreased transiently after enalapril treatment. Cerebral edema and proteinuria were prevented and reduced in SHRSP treated with either an AT1 receptor antagonist or an ACE inhibitor. Survival was markedly and similarly prolonged by both treatments, whether initiated directly before or after development of cerebral edema. In rats where treatment was initiated after manifestation of cerebral edema, both cerebral edema and proteinuria reappeared despite continued treatment. Apparently, when hypertension is sustained, reappearance of target organ damage may not be entirely dependent on angiotensin

Reduction of cerebral injury in stroke-prone spontaneously hypertensive rats by amlodipine

Dihydropyridine Ca2+ channel antagonists, initiated together with high salt intake, prevent the development of hypertension and subsequent cerebral damage in stroke-prone spontaneously hypertensive rats (SHRSP). We hypothesized that the dihydropyridine Ca2+ channel antagonist amlodipine (approximately 15 mg/kg/day) could also reverse established hypertension and cerebral damage. SHRSP drank 1% NaCl from 8 weeks of age. Cerebral damage (cerebral edema and blood–brain barrier integrity) was investigated with magnetic resonance imaging twice a week. Systolic blood pressure was measured weekly. All rats developed severe hypertension and subsequent cerebral damage (defined as day 0). Untreated controls (n=7) died at day 12 (range: 7–28). Oral treatment with amlodipine (n=7), initiated at day 0, reduced systolic blood pressure, reversed cerebral edema and restored blood–brain barrier integrity. Systolic blood pressure remained low and eventually rats died after 450 days (range: 350–580) showing nephrosis but no recurrence of cerebral damage. In conclusion, established hypertension and cerebral damage are reversed by amlodipine in SHRSP

MR imaging of mouse leptomeningeal metastases

To develop new treatment strategies for patients with leptomeningeal metastases (LM), potential therapeutic agents have to be tested in murine models first. In vivo magnetic resonance imaging has an additive value in non-invasive monitoring of the effects of therapeutic agents on LM. Previously, we described a reproducible mouse model for B16F-10 melanoma LM. In this paper, we visualize leptomeningeal melanoma metastases in mice on both T2 weighted MR images and gadolinium diethylenetriaminepentaacetic acid (Gd-DTPA) enhanced T1 weighted MR images, using a 4.7T MR spectrometer. We conclude that both MR sequences can be used to detect and monitor LM of melanoma cells in mice. Our data further suggest that LM are more clearly visualized using T1 weighted Gd-DTPA enhanced subtraction imaging than T2 weighted imaging

Proteinuria precedes cerebral edema in stroke-prone rats : a magnetic resonance imaging study

Background and Purpose: Stroke-prone spontaneously hypertensive rats (SHRSP) subjected to high sodium intake develop severe hypertension, cerebral edema, and proteinuria, culminating in organ damage and early death. MRI, which can be applied serially, provides the unique opportunity to study temporal and quantitative relations between these changes and whether diminution of sodium intake can attenuate established cerebral edema

Blood-brain barrier permeability and monocyte infiltration in experimental allergic encephalomyelitis : a quantitative MRI study

Enhanced cerebrovascular permeability and cellular infiltration mark the onset of early multiple sclerosis lesions. So far, the precise sequence of these events and their role in lesion formation and disease progression remain unknown. Here we provide quantitative evidence that blood–brain barrier leakage is an early event and precedes massive cellular infiltration in the development of acute experimental allergic encephalomyelitis (EAE), the animal correlate of multiple sclerosis. Cerebrovascular leakage and monocytes infiltrates were separately monitored by quantitative in vivo MRI during the course of the disease. Magnetic resonance enhancement of the contrast agent gadolinium diethylenetriaminepentaacetate (Gd-DTPA), reflecting vascular leakage, occurred concomitantly with the onset of neurological signs and was already at a maximal level at this stage of the disease. Immunohistochemical analysis also confirmed the presence of the serum-derived proteins such as fibrinogen around the brain vessels early in the disease, whereas no cellular infiltrates could be detected. MRI further demonstrated that Gd-DTPA leakage clearly preceded monocyte infiltration as imaged by the contrast agent based on ultra small particles of iron oxide (USPIO), which was maximal only during full-blown EAE. Ultrastructural and immunohistochemical investigation revealed that USPIOs were present in newly infiltrated macrophages within the inflammatory lesions. To validate the use of USPIOs as a non-invasive tool to evaluate therapeutic strategies, EAE animals were treated with the immunomodulator 3-hydroxy-3-methylglutaryl Coenzyme A reductase inhibitor, lovastatin, which ameliorated clinical scores. MRI showed that the USPIO load in the brain was significantly diminished in lovastatin-treated animals. Data indicate that cerebrovascular leakage and monocytic trafficking into the brain are two distinct processes in the development of inflammatory lesions during multiple sclerosis, which can be monitored on-line with MRI using USPIOs and Gd-DTPA as contrast agents. These studies also implicate that USPIOs are a valuable tool to visualize monocyte infiltration in vivo and quantitatively assess the efficacy of new therapeutics like lovastatin