Laboratory realization of relativistic pair-plasma beams.

Relativistic electron-positron plasmas are ubiquitous in extreme astrophysical environments such as black-hole and neutron-star magnetospheres, where accretion-powered jets and pulsar winds are expected to be enriched with electron-positron pairs. Their role in the dynamics of such environments is in many cases believed to be fundamental, but their behavior differs significantly from typical electron-ion plasmas due to the matter-antimatter symmetry of the charged components. So far, our experimental inability to produce large yields of positrons in quasi-neutral beams has restricted the understanding of electron-positron pair plasmas to simple numerical and analytical studies, which are rather limited. We present the first experimental results confirming the generation of high-density, quasi-neutral, relativistic electron-positron pair beams using the 440 GeV/c beam at CERN's Super Proton Synchrotron (SPS) accelerator. Monte Carlo simulations agree well with the experimental data and show that the characteristic scales necessary for collective plasma behavior, such as the Debye length and the collisionless skin depth, are exceeded by the measured size of the produced pair beams. Our work opens up the possibility of directly probing the microphysics of pair plasmas beyond quasi-linear evolution into regimes that are challenging to simulate or measure via astronomical observations.

Characterization of Quasi-Keplerian, Differentially Rotating, Free-Boundary Laboratory Plasmas.

We present results from pulsed-power driven differentially rotating plasma experiments designed to simulate physics relevant to astrophysical disks and jets. In these experiments, angular momentum is injected by the ram pressure of the ablation flows from a wire array Z pinch. In contrast to previous liquid metal and plasma experiments, rotation is not driven by boundary forces. Axial pressure gradients launch a rotating plasma jet upward, which is confined by a combination of ram, thermal, and magnetic pressure of a surrounding plasma halo. The jet has subsonic rotation, with a maximum rotation velocity 23±3 km/s. The rotational velocity profile is quasi-Keplerian with a positive Rayleigh discriminant κ^{2}∝r^{-2.8±0.8} rad^{2}/s^{2}. The plasma completes 0.5-2 full rotations in the experimental time frame (∼150 ns).

Perpendicular Subcritical Shock Structure in a Collisional Plasma Experiment.

We present a study of perpendicular subcritical shocks in a collisional laboratory plasma. Shocks are produced by placing obstacles into the supermagnetosonic outflow from an inverse wire array z pinch. We demonstrate the existence of subcritical shocks in this regime and find that secondary shocks form in the downstream. Detailed measurements of the subcritical shock structure confirm the absence of a hydrodynamic jump. We calculate the classical (Spitzer) resistive diffusion length and show that it is approximately equal to the shock width. We measure little heating across the shock (<10% of the ion kinetic energy) which is consistent with an absence of viscous dissipation.

An imaging refractometer for density fluctuation measurements in high energy density plasmas.

We report on a recently developed laser-probing diagnostic, which allows direct measurements of ray-deflection angles in one axis while retaining imaging capabilities in the other axis. This allows us to measure the spectrum of angular deflections from a laser beam, which passes through a turbulent high-energy-density plasma. This spectrum contains information about the density fluctuations within the plasma, which deflect the probing laser over a range of angles. We create synthetic diagnostics using ray-tracing to compare this new diagnostic with standard shadowgraphy and schlieren imaging approaches, which demonstrates the enhanced sensitivity of this new diagnostic over standard techniques. We present experimental data from turbulence behind a reverse shock in a plasma and demonstrate that this technique can measure angular deflections between 0.06 and 34 mrad, corresponding to a dynamic range of over 500.

Collective optical Thomson scattering in pulsed-power driven high energy density physics experiments (invited).

Optical collective Thomson scattering (TS) is used to diagnose magnetized high energy density physics experiments at the Magpie pulsed-power generator at Imperial College London. The system uses an amplified pulse from the second harmonic of a Nd:YAG laser (3 J, 8 ns, 532 nm) to probe a wide diversity of high-temperature plasma objects, with densities in the range of 1017-1019 cm-3 and temperatures between 10 eV and a few keV. The scattered light is collected from 100 µm-scale volumes within the plasmas, which are imaged onto optical fiber arrays. Multiple collection systems observe these volumes from different directions, providing simultaneous probing with different scattering K-vectors (and different associated α-parameters, typically in the range of 0.5-3), allowing independent measurements of separate velocity components of the bulk plasma flow. The fiber arrays are coupled to an imaging spectrometer with a gated intensified charge coupled device. The spectrometer is configured to view the ion-acoustic waves of the collective Thomson scattered spectrum. Fits to the spectra with the theoretical spectral density function S(K, ω) yield measurements of the local plasma temperatures and velocities. Fitting is constrained by independent measurements of the electron density from laser interferometry and the corresponding spectra for different scattering vectors. This TS diagnostic has been successfully implemented on a wide range of experiments, revealing temperature and flow velocity transitions across magnetized shocks, inside rotating plasma jets and imploding wire arrays, as well as providing direct measurements of drift velocities inside a magnetic reconnection current sheet.

Haemochromatosis: understanding the mechanism of disease and implications for diagnosis and patient management following the recent cloning of novel genes involved in iron metabolism.

Haemochromatosis, a common recessive genetic disorder in people of Northern European descent, is an iron storage disorder characterized by excessive hepatic iron accumulation resulting from disruption of the regulation of intestinal iron absorption. The identification of novel genes involved in the control of iron absorption from the diet has allowed improved understanding of iron metabolism in health and disease. In particular, the identification of the haemochromatosis gene (HFE) and more recently the transferrin receptor 2 gene (TfR2) together with the specific mutations in these genes which result in hepatic iron overload, has enhanced our understanding of the pathophysiology of haemochromatosis. However, because of the wide variation in phenotypic expression of the disease, there now exists a considerable challenge to diagnosis and patient management.

Interrelationships of alcohol and iron in liver disease with particular reference to the iron-binding proteins, ferritin and transferrin.

It is known that the regular consumption of alcohol is responsible for the disruption of normal iron metabolism in humans, resulting in the excess deposition of iron in the liver in approximately one-third of alcoholic subjects. The mechanisms involved are largely unknown; however, it is likely that the two major proteins of iron metabolism, ferritin and transferrin are intimately involved in the process. Tissue damage in alcoholic liver disease and the inherited iron-overload disease, haemochromatosis, are caused by excess alcohol and iron, respectively. The mechanisms of this damage are believed to be similar in both disease conditions and involve free radical-mediated toxicity. A high proportion of haemochromatosis sufferers consume excessive amounts of alcohol and synergistic hepatotoxic events may occur leading to the earlier development of liver cirrhosis. This review describes briefly the role of ferritin and transferrin in normal iron metabolism and in iron overload disease and explores the possible involvement of these proteins in the pathophysiology of excess iron deposition in alcoholic subjects.

Hemochromatosis and iron needs.

Although iron is an essential dietary requirement, the amount absorbed by the body is well regulated and depends on body iron stores and on dietary iron availability. There is very little iron excreted under normal conditions. Iron deficiency is a worldwide problem but iron overload, as seen in the inherited disease, hemochromatosis, is a major cause of morbidity in some Caucasian populations. This is a problem particularly where there is an adequate dietary iron intake and especially in males. A mutation has recently been described in an MHC Class l-like gene (HFE) that encodes for a protein (HFE) of 343 amino acids. The molecule contains a signal sequence peptide-binding region, alpha, and alpha(2) domains, and an immunoglobulinlike alpha(3) domain, in addition to a transmembrane region and a small cytoplasmic tail. It is a candidate gene for hemochromatosis. Several possibilities as to the function of this gene and the corresponding protein have been suggested but none has yet been confirmed. The mutation has been detected by several different groups in 80%-100% of subjects with the disease. However, in one study, 18%-20% of patients with the mutation did not exhibit significant iron overload. The discovery of this gene has important implications for both clinical studies and the elucidation of the pathways of iron metabolism.

Distribution of transferrin saturation in an Australian population: relevance to the early diagnosis of hemochromatosis.

BACKGROUND & AIMS: An elevated transferrin saturation is the earliest phenotypic abnormality in hereditary hemochromatosis. Determination of transferrin saturation remains the most useful noninvasive screening test for affected individuals, but there is debate as to the appropriate screening level. The aims of this study were to estimate the mean transferrin saturation in hemochromatosis heterozygotes and normal individuals and to evaluate potential transferrin saturation screening levels. METHODS: Statistical mixture modeling was applied to data from a survey of asymptomatic Australians to estimate the mean transferrin saturation in hemochromatosis heterozygotes and normal individuals. To evaluate potential transferrin saturation screening levels, modeling results were compared with data from identified hemochromatosis heterozygotes and homozygotes. RESULTS: After removal of hemochromatosis homozygotes, two populations of transferrin saturation were identified in asymptomatic Australians (P < 0.01). In men, 88.2% of the truncated sample had a lower mean transferrin saturation of 24.1%, whereas 11.8% had an increased mean transferrin saturation of 37.3%. Similar results were found in women. A transferrin saturation threshold of 45% identified 98% of homozygotes without misidentifying any normal individuals. CONCLUSIONS: The results confirm that hemochromatosis heterozygotes form a distinct transferrin saturation subpopulation and support the use of transferrin saturation as an inexpensive screening test for hemochromatosis. In practice, a fasting transferrin saturation of > or = 45% identifies virtually all affected homozygous subjects without necessitating further investigation of unaffected normal individuals.

Mapping the gene for sex-linked anemia: an inherited defect of intestinal iron absorption in the mouse.

The sex-linked anemic (sla) mouse carries an anemia that results from an inherited defect of intestinal iron absorption and provides an ideal model with which to investigate this poorly understood yet clinically important process. We have precisely mapped the sla locus within the central region of the X chromosome in relation to a panel of microsatellite markers. Analysis of over 500 progeny from an intraspecific intercross and a smaller intraspecific backcross segregating sla established the following locus order in the sla region: DXMit45-sla- (DXMit16, DXMit96)-DXMit41-DXMit169-DXMit170- DXMit148-(DXMit18, DXMit171)-DXMit84-DXMit64. The two microsatellites DXMit16 and DXMit96 are located 0.60 +/- 0.35cM from sla and form the telomeric limit of the sla region. The mapping of the sla locus is an important first step to identifying the gene itself.

Ultrastructural sequences during liver iron overload in genetic hemochromatosis.

BACKGROUND/AIMS: The pathway through which iron contributes to liver cell damage and cirrhosis in genetic hemochromatosis is not clear. The objective of the present study was to describe the ultrastructural changes in liver biopsies of patients in various stages of this condition and to correlate these with clinical, histopathological and biochemical data. METHODS: Liver biopsies from 20 patients with genetic hemochromatosis were examined by transmission electron microscopy. The use of unstained thin (60 nm) sections facilitated the identification and localization of the electron-opaque compounds ferritin and hemosiderin in various liver cells. Stained thin sections permitted evaluation of the concomitant subcellular damage and collagen deposition. The ultrastructural observations were corroborated with the histopathological findings and biochemical data. RESULTS: All patients had liver iron overload, which was classified as mild, moderate or severe. In the stage of mild overload (hepatic iron concentration HIC 93.5+/-23.3 micromol/g and hepatic iron index HII 2.3+/-0.7), cytosolic ferritin and scarce pericanalicular lysosomes (siderosomes) were seen in periportal hepatocytes (acinar zone 1), without evidence of organelle damage, and in the absence of sinusoidal cell siderosis. In moderate overload (HIC 190.8+/-41.5 micromol/g and HII 4.3+/-1.9), ferritin was identified in hepatocytes of all acinar zones, and the pericanalicular siderosomes were abundant, especially in acinar zone 1. Single hepatocytes showed organelle damage and occasional sinusoidal cells showed siderosis. In severe overload (HIC 308+/-49.0 micromol/g and HII 7.5+/-1.7), hepatocytes of all acinar zones were filled with large, hemosiderin-containing siderosomes, and changes in mitochondria, smooth and rough endoplasmic reticulum and nuclei were conspicuous. Marked sinusoidal cell siderosis and collagen deposition were observed predominantly in this stage. CONCLUSIONS: Electron microscopy has shown that during the long, latent stage of "compensated" genetic hemochromatosis, hepatocytes display only minimal subcellular changes, other than iron overload. "Decompensated" overload, characterized by extensive subcellular pathology and focal necrosis, is reached when 1) the hepatocytic siderosis is generalized (i.e. beyond pericanalicular polarization of siderosomes in hepatocytes, and beyond zone 1 in the acinus); and 2) there is evidence of massive siderosis of sinusoidal cells. These findings support the concept of a critical level of hepatic iron concentration beyond which organelle damage is conspicuous and liver cell injury may become irreversible.

Analysis of the cost of population screening for haemochromatosis using biochemical and genetic markers.

AIMS: To estimate the cost of population screening for haemochromatosis in Australia and to compare the cost of alternative screening strategies. METHODS: The costs of screening for haemochromatosis were analysed in a hypothetical study using transferrin saturation as the primary screening test, with confirmation of the diagnosis by either liver biopsy or DNA testing for the recently-described haemochromatosis gene. RESULTS: Screening, with confirmation of the diagnosis by liver biopsy, would cost between US$5079 and US$8813 per case detected (excluding administrative costs), depending on the screening strategy (Aust$ = US$0.80). If a DNA test were used instead of liver biopsy, the cost would be reduced to an estimated US$3954-US$4410 per case. This would be further reduced to US$2457 by detection of additional cases by screening family members. The least costly strategy utilised a transferrin saturation threshold of 55% and DNA testing for confirmation of the diagnosis; however, a transferrin saturation threshold of 45% increased the cost only marginally. The initial screening step (transferrin saturation) accounted for 74%-94% of the estimated cost of the screening programme. CONCLUSIONS: Screening for haemochromatosis using transferrin saturation involves relatively modest costs which may be recovered if complications of haemochromatosis can be prevented by early detection and treatment. The most cost-effective strategies utilised transferrin saturation for initial screening, followed by DNA testing. Reduction in the cost of transferrin saturation would lead to a significant reduction in total screening costs. Additional benefits of a screening programme include detection of other iron overload disorders and iron deficiency.

Evidence that "myofibroblast-like" cells are the cellular source of capsular collagen in hepatocellular carcinoma.

BACKGROUND/AIMS: The prognosis for patients with hepatocellular carcinoma is poor although tumour encapsulation has been associated with improved survival and disease-free rates. While the source of the tumour capsule is unclear, the major role that activated hepatic stellate cells play in the deposition of liver matrix in normal and diseased states suggests the possible involvement of these cells in tumour encapsulation. METHODS: Twenty-four liver tumours (seven encapsulated HCC, seven non-encapsulated HCC, 10 colorectal metastases) were studied. Activated hepatic stellate cells were identified by immunohistochemistry for alpha-smooth muscle actin (alpha-SMA) and in situ hybridization for pro-collagen alpha1 (I) mRNA. Collagen deposition was localized using Masson's trichrome stain. RESULTS: Pro-collagen alpha1 (I) mRNA co-localized to alpha-SMA positive hepatic stellate cells within the region of increased collagen deposition in (i) the tumour capsule of encapsulated HCC, and (ii) the tumour junction of non-encapsulated HCC and colorectal metastasis. In addition, there was marked peritumour expression of alpha-SMA and procollagen alpha1 (I) mRNA, which diminished with distance away from the tumour in all tumour groups. The degree of expression was greatest with encapsulated HCC, less with non-encapsulated HCC and least with colorectal metastasis. This contrasted with the absence of alpha-SMA expression in normal liver from the same patients. Within the tumours, colorectal metastases differed from HCC by demonstrating marked alpha-SMA expression and collagen deposition in the septa. CONCLUSIONS: Our findings demonstrate that activated hepatic stellate cells (i) are responsible for increased peritumour collagen production in non-encapsulated HCC and colorectal metastasis, and (ii) may be implicated in tumour capsule formation in HCC and metastasis stroma development. Thus, stellate cells may influence the local hepatic invasion by these tumours.

Hepatic stellate cell activation in genetic haemochromatosis. Lobular distribution, effect of increasing hepatic iron and response to phlebotomy.

BACKGROUND/AIMS: Activated hepatic stellate cells produce increased levels of collagen in animal models of chronic iron overload; however, their role in human genetic haemochromatosis is unknown. This study examined the relationship between hepatic iron concentration and hepatic stellate cell activation in genetic haemochromatosis. METHODS: Liver biopsies from 75 patients (55 with haemochromatosis, 14 haemochromatosis patients both pre- and post-phlebotomy and six non iron-loaded disease control subjects) were stained for iron using Perls' Prussian Blue. Thirty biopsies in which there was no evidence of either steatosis or inflammation were subjected to immunohistochemistry for alpha-smooth muscle actin and desmin and counterstained for iron. Forty-five biopsies demonstrated either steatosis or inflammation, in addition to excess iron. RESULTS: Stellate cells were identified by light microscopy as perisinusoidal cells containing numerous intracellular fat droplets. alpha-Smooth muscle actin was detected in biopsies with an hepatic iron concentration >60 micromol/g dry weight. Increasing hepatic iron concentration and hepatic iron index correlated with an increase in alpha-smooth muscle actin expression (r=0.81 and 0.72, respectively). Phlebotomy resulted in a significant decrease in alpha-smooth muscle actin expression. In early disease prior to histological evidence of collagen deposition, whilst activated stellate cells were located in Zone 1, greater numbers were found in Zones 2 and 3 distal to the region of heaviest iron overload. CONCLUSIONS: This study has demonstrated for the first time in humans a correlation between hepatic iron concentration and stellate cell activation in haemochromatosis, which is reversed by iron removal. Humoral factors from either iron-loaded hepatocytes or activated Kupffer cells may be responsible for early stellate cell activation in areas of the liver remote from heavy iron loading.

Concentrations of transferrin and carbohydrate-deficient transferrin in postmortem human brain from alcoholics.

Transferrin (T f) and its carbohydrate-deficient isoform (CDT) were measured by radioimmunoassay in phosphate-buffered saline extracts of two informative areas of cerebral cortex tissue obtained at autopsy from alcoholics without other associated disease (n = 4); alcoholics with cirrhosis of the liver (n = 4) and agematched controls (n = 4). Total T f was also measured in two informative cortical areas from five dementia cases. All cases were male. Total immunoreactive T f was assayed directly in the extract, CDT immunoreactivity in the concentrated eluate after the sialylated form was removed by passing through DEAE-Sephacel at pH 5.65. Brain CDT averaged 10% of total T f overall. Although replicate extractions of individual samples gave consistent assays for both substances, there was wide variation both between different cortical areas from a given case and between cases within groups. There were no significant differences between total T f levels in uncomplicated alcoholics, dementia cases and controls, but cirrhotic alcoholics gave significantly higher values. The CDT: T f ratio was not increased in the brains of either group of alcoholics compared to controls. Whereas the serum CDT: T f ratio is an excellent marker of recent alcohol consumption, brain T f and CDT concentrations do not mark alcoholism nor dementia, and their biological variability diminishes their usefulness as disease indices. However, brain T f may be a marker of cirrhosis-induced changes.

Effect of the microtubular inhibitor vinblastine on ferritin clearance and release in the rat.

We have previously demonstrated that colchicine inhibits ferritin clearance from the circulation of normal and iron-loaded rats and stimulates endogenous ferritin release into both the serum and bile of iron-loaded rats. The aim of the present study was to determine the effect of vinblastine on ferritin clearance and release in normal and iron-loaded rats. Vinblastine was administered at either 1 or 10 mg/kg to both normal and iron-loaded rats, infused over a 5 h period with either a rat liver ferritin or saline solution. Serum and biliary ferritin levels were determined every 30 min. After 5 h, 90% of the infused ferritin was cleared from the circulation in the absence of vinblastine. Low-dose vinblastine decreased ferritin uptake 10-20% in iron-loaded rats. High-dose vinblastine inhibited ferritin clearance by 25% in normal rats and 20-40% in iron-loaded rats. Vinblastine administration caused a 2-3-fold increase in the serum ferritin concentration and a 3-5-fold peak in biliary ferritin levels. Thus, vinblastine caused the release of endogenous ferritin into both the serum and bile of iron-loaded rats in the presence of a ferritin load. We therefore conclude that disturbed microtubule function accounts for the observed inhibition of ferritin uptake and intracellular transport; however, the mechanism of increased ferritin release remains unclear.

Hepatic iron deposition in human disease and animal models.

Iron deposition occurs in parenchymal cells of the liver in two major defects in human subjects (i) in primary iron overload (genetic haemochromatosis) and (ii) secondary to anaemias in which erythropolesis is increased (thalassaemia). Transfusional iron overload results in excessive storage primarily in cells of the reticule endothelial system. The storage patterns in these situations are quite characteristic. Excessive iron storage, particularly in parenchymal cells eventually results in fibrosis and cirrhosis. There is no animal model or iron overload which completely mimics genetics haemochromatosis but dietary iron loading with carbonyl iron or ferrocene does produce excessive parenchymal iron stores in the rat. Such models have been used to study iron toxicity and the action of iron chelators in the effective removal of excessive iron stores.

Factors influencing disease expression in hemochromatosis.

Genetic hemochromatosis is one of the most common inherited disorders in Caucasian populations. The disease frequency in Caucasian populations in Australia, Europe, and the United States is 1:300-400. The basic genetic defect remains unknown, although the hemochromatosis gene is closely linked to histocompatibility antigen (HLA) A, thus allowing early diagnosis in members of affected families. Many factors-environmental, genetic, and nongenetic in nature-influence the degree of iron loading in affected individuals. In particular, pathologic and physiologic blood loss and blood donation influence iron stores in hemochromatosis. The iron concentration in the liver is an important determinant of survival because a hepatic iron concentration in excess of 400 mumol/g dry weight is usually associated with cirrhosis. Patients with cirrhosis secondary to hemochromatosis are at risk of heptocellular carcinoma and complications of portal hypertension. The combination of improved awareness of the condition and the use of HLA typing to identify affected family members has led to earlier diagnosis and therapy, and to an improvement in overall survival.

Evidence that the ancestral haplotype in Australian hemochromatosis patients may be associated with a common mutation in the gene.

Hemochromatosis (HC) is a common inherited disorder of iron metabolism for which neither the gene nor biochemical defect have yet been identified. The aim of this study was to look for clinical evidence that the predominant ancestral haplotype in Australian patients is associated with a common mutation in the gene. We compared indices of iron metabolism and storage in three groups of HC patients categorized according to the presence of the ancestral haplotype (i.e., patients with two copies, one copy, and no copies of the ancestral haplotype). We also examined iron indices in two groups of HC heterozygotes (those with the ancestral haplotype and those without) and in age-matched controls. These analyses indicate that (i) HC patients with two copies of the ancestral haplotype show significantly more severe expression of the disorder than those with one copy or those without, (ii) HC heterozygotes have partial clinical expression, which may be influenced by the presence of the ancestral haplotype in females but not in males, and (iii) the high population frequency of the HC gene may be the result of the selective advantage conferred by protecting heterozygotes against iron deficiency.