We present the results of a prospective, randomised study comparing PBPC and BM focusing on engraftment, acute and chronic GVHD and survival. Forty patients with haematological malignancies received HLA-identical sibling BM (group A) or PBPC (group B). Evaluable patients were 19 (A) and 18 (B). Median age was 35 (17-56) in A and 29.5 (9-51) in B. Conditioning was mainly Bu-Cy2; GVHD prophylaxis was CSA-MTX. PBPC were harvested after 5 days of G-CSF 10 microg/kg/day. Median days for an ANC >0.5 x 10(9)/l was 18 (13-30) in A and 16 (11-25) in B (P = 0.10). Platelets >20 x 10(9)/l occurred at +17 (10-40) in A and +12 (9-36) in B (P = 0.01). The probability of > or =2 grade a-GVHD was 19% (A) and 27% (B) (P = 0.53). The probability of all grade c-GVHD was 70% with BM. In spite of the small number of patients in group B (PBPC), our data suggest the great majority of them will have c-GVHD (P = 0.08); extensive disease was present in 50 and 100%, respectively (P = 0.05). The estimates of overall survival for A and B at 1000 days are 51 and 47%, respectively (P = 0.67); DFS at 1000 days are 52 and 58%, respectively (P = 0.50). PBPC resulted in faster platelet engraftment. The incidence of acute and chronic GVHD was similar in both groups, but the severity of c-GVHD was higher with PBPC. No differences in survival and DFS have been observed to date.
Using vitreous fluorophotometry and quantitative fluorescence microscopy the authors studied the permeability of the blood-retinal barrier (BRB) to fluorescein in control and in 8 days streptozotocin-induced diabetic rats. Vitreous fluorophotometry showed that fluorescein permeates BRB in control and in diabetic rats. However, in diabetic rats the permeability to fluorescein was significantly increased as compared to control rats. The vitreous penetration ratio (VPR) values for total and free fluorescein at 60 min, were higher for diabetic rats (231.2+/-12.9 min-1 for total fluorescein and 1299.24+/-58.0 min-1 for free fluorescein) than for control rats (95.5+/-3.5 min-1 for total fluorescein and 646.6+/-55. 0 min-1 for free fluorescein) (P<0.05). Quantitative confocal fluorescence microscopy confirmed these findings and identified the site of leakage across the BRB by comparing the relative importance of the fluorescein leakage across the outer and inner BRB. In control rats the fluorescence levels remained relatively low in the photoreceptor layer, next to the outer BRB but in the inner nuclear layer, next to the inner BRB reached values that were almost ten times higher. These results suggest that in retinas of control rats fluorescein penetrates predominantly through the inner BRB. In diabetic rats the fluorescence levels in the photoreceptor and in the inner nuclear layer were significantly increased as compared to the fluorescence levels in controls rats. Nevertheless, in the inner nuclear layer the fluorescence levels were also generally higher than the fluorescence levels at the photoreceptor layer. The rates of fluorescence levels between the inner nuclear layer and the photoreceptor layer were apparently 3:1, 60 min after the single intravenous injection of fluorescein. Also, the fluorescein penetration in the inner nuclear layer of the diabetic rats is higher than that observed in the inner nuclear layer of the control rats (P<0.001). These findings suggest that the permeability to fluorescein of both components of the BRB is increased 8 days after the induction of diabetes by streptozotocin and that the permeability of the retinal vasculature is preferentially affected.
Human studies addressing the long-term effects of peripheral retinal degeneration on visual cortical function and structure are scarce. Here we investigated this question in patients with Retinitis Pigmentosa (RP), a genetic condition leading to peripheral visual degeneration. We acquired functional and anatomical magnetic resonance data from thirteen patients with different levels of visual loss and twenty-two healthy participants to study primary (V1) visual cortical retinotopic remapping and cortical thickness. We identified systematic visual field remapping in the absence of structural changes in the primary visual cortex of RP patients. Remapping consisted in a retinotopic eccentricity shift of central retinal inputs to more peripheral locations in V1. Importantly, this was associated with changes in visual experience, as assessed by the extent of the visual loss, with more constricted visual fields resulting in larger remapping. This pattern of remapping is consistent with expansion or shifting of neuronal receptive fields into the cortical regions with reduced retinal input. These data provide evidence for functional changes in V1 that are dependent on the magnitude of peripheral visual loss in RP, which may be explained by rapid cortical adaptation mechanisms or long-term cortical reorganization. This study highlights the importance of analyzing the retinal determinants of brain functional and structural alterations for future visual restoration approaches.
It is unknown whether independent neural damage may occur in the pre-/absent vascular diabetic retinopathy (DR). To exclude vasculopathy, it is important to measure the integrity of the blood-retinal barrier (BRB). This cross-sectional study addressed this problem in type 1 diabetic patients with normal ocular fundus and absent breakdown of the BRB (confirmed with vitreous fluorometry). These were compared with a group with disrupted BRB (with normal fundus or initial DR) and normal controls. Multifocal electroretinography and chromatic/achromatic contrast sensitivity were measured in these 42 patients with preserved visual acuity. Amplitudes of neurophysiological responses (multifocal electroretinogram) were decreased in all eccentricity rings in both clinical groups, when compared with controls, with sensitivity >78% for a specificity level of 90%. Implicit time changes were also found in the absence of initial DR. Impaired contrast sensitivity along chromatic axes was also observed, and achromatic thresholds were also different between controls and both clinical groups. The pattern of changes in the group without baseline BRB permeability alterations, as probed by psychophysical and electrophysiological measurements, does thereby confirm independent damage mechanisms. We conclude that retinal neuronal changes can be diagnosed in type 1 diabetes, independently of the breakdown of the BRB and onset of vasculopathy.
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