Time-dependent effects of focal retinal ischemia on axonal cytoskeleton proteins.

PURPOSE: To examine the time-dependent effects of focal axonal ischemia on the retinal ganglion cell (RGC) cytoskeleton. METHODS: Eight pigs were used. Small retinal arteriolar branches were occluded by argon laser to induce focal ischemic insults that were maintained for a period of 6 hours or 1 hour. Treated and untreated retinal segments were dissected from the eye after euthanatization. Each retinal segment followed the longitudinal projection of RGC axons from peripheral retina to the optic disc. Antibodies to phosphorylated neurofilament heavy, phosphorylation-independent neurofilament heavy (NFH), neurofilament light, neurofilament medium, microtubule, and microtubule-associated proteins were used to study the axonal cytoskeleton. Glial fibrillary acidic protein and TUNEL staining were also used to examine astrocyte and apoptotic changes, respectively. Comparisons were made between treated and untreated retinal segments. RESULTS: Cytoskeleton protein changes occurred within ischemic regions and also within retinal tissue on the disc side and peripheral side of the ischemic regions. NFH and microtubule proteins were the earliest cytoskeleton subunits that underwent change. Changes to all cytoskeleton proteins, apart from NFH, occurred in a time-dependent manner within regions of ischemia. In the time points studied, cytoskeleton changes occurred in the absence of detectable astrocyte changes and RGC apoptosis. CONCLUSIONS: An ischemic insult induces RGC cytoskeleton protein change, implying that the local environment plays an important role in modulating axonal structure and function. Cytoskeleton proteins are likely to be important pathogenic mediators of neuronal dysfunction in diseases such as glaucoma and retinal vascular disease.

Comparison of femoral and auricular arterial blood pressure monitoring in pigs.

OBJECTIVE: To compare arterial blood pressure measurements obtained from the femoral and auricular arteries in anaesthetized pigs. STUDY DESIGN: Prospective experimental study. ANIMALS: Fifteen female Large White pigs were used weighing 21.3 +/- 2.3 kg. METHODS: The pigs were anaesthetized with tiletamine/zolazepam and xylazine administered intramuscularly, and anaesthesia maintained with isoflurane delivered in oxygen/nitrogen. Arterial oxygen partial pressures were maintained between 11.3 and 13.3 kPa and PaCO(2) between 4.6 and 6.0 kPa. Monitoring included electrocardiogram, capnography and invasive blood pressure. The auricular and femoral arteries were catheterized for continuous systolic (SAP), diastolic (DAP) and mean arterial pressure (MAP) measurements. Measurements were recorded every 15 minutes. Statistical analysis involved a Bland-Altman plot analysis. RESULTS: The mean difference +/- confidence intervals between the femoral and the auricular arterial diastolic, systolic and mean blood pressure measurements during hypotension were 2 +/- 7, 2 +/- 5 and 2 +/- 5 mmHg respectively. In conditions of normotension mean difference +/- confidence intervals, of femoral and auricular arterial blood pressure measurements of diastolic, systolic and mean blood pressure were 4 +/- 5, 3 +/- 7 and 4 +/- 4 mmHg respectively. In conditions of increased arterial blood pressure, mean difference +/- confidence intervals, of femoral and auricular arterial blood pressure measurements of diastolic, systolic and mean blood pressure were 4 +/- 5, 3 +/- 8 and 4 +/- 4 mmHg respectively. CONCLUSION: Auricular artery catheterization is easier and quicker to perform. Pressure measurements from the auricular artery compared well with the femoral artery. CLINICAL RELEVANCE: We found that auricular arterial blood pressures were similar to femoral arterial values under the conditions of this experiment. We did not test extremes of blood pressure or significant alterations in body temperature.

Mitochondrial cytochrome c oxidase expression in the central nervous system is elevated at sites of pressure gradient elevation but not absolute pressure increase.

The paucity of suitable experimental models has made it difficult to isolate the pathogenic role of mitochondria in central nervous system diseases associated with absolute pressure elevation and increased pressure gradients. Experimental models of traumatic brain injury (TBI) and hydrocephalus have been useful for examining the mitochondrial response following pressure increase in the central nervous system; however, the presence of multiple pathogenic factors acting on the brain in these previous studies has made it difficult to determine whether the induced changes were a result of mechanical damage, intracranial pressure elevation, or other pathogenic factors. By direct monitoring and control of pressures in the intraocular, intracranial, and vascular compartments, we use the pig optic nerve, a typical central white matter tract, to compare the temporal sequence of cytochrome c oxidase (CcO) levels between regions of absolute pressure elevation and pressure gradient increase. We demonstrate that a rise in pressure gradient without traumatic injury up-regulates CcO levels across the site of the gradient, in a manner similar to what has been previously reported for hydrocephalus. We also demonstrate that CcO changes do not occur following an absolute pressure rise. These findings taken together with our recent reports suggest that mitochondria initiate an early compensatory response to axonal damage following pressure gradient increase. Extrapolation of our results also suggests that decreased CcO levels in TBI may be secondary to mechanical damage. This study emphasises the importance of pressure gradients in regulating mitochondrial function in the central nervous system.

Protective role of endothelial nitric oxide synthase following pressure-induced insult to the optic nerve.

Although intracranial pressure (ICP) elevation can induce significant structural and functional changes within the central nervous system (CNS), almost complete neuronal recovery is possible if ICP and associated pathogenic factors are restored in the acute phase of the disease process. Nitric oxide synthase (NOS) isoforms have been implicated in the pathogenesis of many CNS diseases and may play an important role in the development of neuronal tolerance in the early stages of pressure elevation. In this paper we use the pig optic nerve, a typical central white matter tract, to study the time-dependent sequence of NOS isoform change following pressure elevation. The timing of NOS isoform change in relationship to structural and functional changes to axons and glial cells is also discussed. This study demonstrates that endothelial cell nitric oxide synthase (ecNOS), an enzyme that plays a protective role in the CNS, is up-regulated in a time-dependent manner after pressure elevation. ecNOS levels increase after axonal and astrocyte injury, suggesting that it might be a compensatory response that is initiated in an effort to preserve CNS function. Inducible NOS (iNOS) and neuronal NOS (nNOS), which are known to have a deleterious effect on the CNS, were not detected in this study. The increase in ecNOS demonstrated in this study is significantly different to the increase in iNOS and nNOS previously demonstrated following traumatic brain injury. Changes in ecNOS levels may therefore be important in the development of neuronal tolerance in the early stages of CNS diseases such as hydrocephalus.

Elevated pressure induced astrocyte damage in the optic nerve.

Astrocytes maintain an intimate relationship with central nervous system (CNS) neurons and play a crucial role in regulating their biochemical environment. A rise in neural tissue pressure in the CNS is known to lead to axonal degeneration however the response of astrocytes during the early stages of neural injury has not been studied in great detail. The optic nerve is a readily accessible model in which to study CNS axonal injury. Previous work from our laboratory has shown that an acute increase in intraocular pressure (IOP) results in axonal cytoskeleton changes and axonal transport retardation within the optic nerve head. Axonal changes occurred in a time-dependent manner with the magnitude of change being proportional to the duration of the IOP rise. Using glial fibrillary acidic protein (GFAP) as a marker of astrocytes we have now studied pressure induced changes in astrocyte structure in the optic nerve head. Using confocal microscopy we found that an increase in IOP resulted in morphological changes in the astrocytes that were consistent with previous reports of swelling. In addition there was also a decrease in GFAP intensity within these astrocytes. These changes occurred in a time-dependent manner with the chronology of change coinciding with that of axonal change. There was no evidence of apoptosis in regions where astrocyte changes were found. The present results provide evidence that in the early stages of neural tissue pressure rise there are both astrocyte and axonal injury.

Time-dependent effects of elevated intraocular pressure on optic nerve head axonal transport and cytoskeleton proteins.

PURPOSE: To study the time-dependent effects of elevated intraocular pressure (IOP) on axonal transport and cytoskeleton proteins in the porcine optic nerve head. METHODS: Fifteen pigs were used for this study. Rhodamine-beta-isothiocyanate was injected into the vitreous of each eye to study axonal transport. IOP in the left eye was elevated to 40 to 45 mm Hg, and IOP in the right eye was maintained between 10 and 15 mm Hg. Cerebrospinal fluid pressure was also continually monitored. IOP was elevated for 3 hours (n = 7) or 12 hours (n = 8) before animal euthanatization. Antibodies to phosphorylated neurofilament heavy (NFHp), phosphorylation-independent neurofilament heavy (NFH), neurofilament light, neurofilament medium (NFM), microtubule, and microtubule-associated protein (MAP) were used to study the axonal cytoskeleton. Confocal microscopy was used to compare axonal transport and cytoskeleton change between control and high IOP eyes in different laminar regions and quadrants of the optic nerve head. Results from these experiments were also compared with 6-hour elevated IOP data from an earlier study. RESULTS: Three hours of IOP elevation caused a decrease in NFH, NFHp, and NFM within laminar regions, with no demonstrable change in axonal transport. Changes to MAP and microtubules were only seen after 12 hours of IOP elevation. Axonal transport change occurred in a time-dependent manner with peripheral nerve bundle changes occurring earlier and being greater than central nerve bundle changes. CONCLUSIONS: Time-dependent changes in axonal transport and cytoskeletal structure in the optic nerve head provide further pathogenic evidence of axonal damage caused by elevated IOP.

Axonal transport and cytoskeletal changes in the laminar regions after elevated intraocular pressure.

PURPOSE: To investigate the axonal cytoskeleton changes occurring in the prelaminar region, lamina cribrosa, and postlaminar region of the porcine optic nerve after an acute increase in intraocular pressure (IOP) and whether this corresponds with axonal transport abnormalities. METHODS: Six white Landrace pigs were used. The left eye IOP was elevated to 40 to 45 mm Hg for 6 hours, and the right eye IOP was maintained between 10 and 15 mm Hg. Rhodamine-beta-isothiocyanate (RITC) was injected into the vitreous of each eye at the beginning of the experiment, to study axonal transport. After euthanasia, optic nerves were removed and prepared for axonal transport and cytoskeleton studies. Antibodies to phosphorylated neurofilament heavy (NFHp), phosphorylation-independent neurofilament heavy (NFH), neurofilament light (NFL), neurofilament medium (NFM), microtubule, and microtubule-associated protein (MAP) were used to study the axonal cytoskeleton. Montages of confocal microscopy images were quantitatively analyzed to investigate simultaneous changes in optic nerve axonal transport and cytoskeletal proteins in the high-IOP and control eyes. RESULTS: Axonal transport of RITC was reduced in the prelaminar, lamina cribrosa, and proximal 400 mum of the postlaminar optic nerve regions in the high-IOP eye. NFHp, NFM, and NFH were significantly reduced in the prelaminar, lamina cribrosa, and proximal postlaminar regions in the high-IOP eye. No differences in NFL, MAP, and tubulin staining were detected. CONCLUSIONS: Elevated IOP induced both axonal transport and cytoskeleton changes in the optic nerve head. Changes to the cytoskeleton may contribute to the axonal transport abnormalities that occur in elevated IOP.