Phase III randomized study of the proposed adalimumab biosimilar GP2017 in psoriasis: impact of multiple switches.

BACKGROUND: Adalimumab is used to treat several inflammatory diseases, including plaque psoriasis. GP2017 is a proposed adalimumab biosimilar. OBJECTIVES: To assess the impact of multiple switches between GP2017 and reference adalimumab (ref-ADMB) following the demonstration of equivalent efficacy and similar safety and immunogenicity, in adult patients with active, clinically stable, moderate-to-severe plaque psoriasis. METHODS: This 51-week double-blinded, phase III study randomly assigned patients to GP2017 (n = 231) or ref-ADMB (n = 234) 80 mg subcutaneously at week 0, then 40 mg biweekly from week 1. At week 17, patients were rerandomized to switch (n = 126) or continue (n = 253) treatment. The primary end point was patients achieving ≥ 75% improvement in Psoriasis Area and Severity Index (PASI 75) at week 16, with equivalence confirmed if the 95% confidence interval (CI) for the difference in PASI 75 between treatments was ± 18%. The key secondary end point was the change from baseline to week 16 in continuous PASI. Other end points were PASI over time; PASI 50, 75, 90 and100; pharmacokinetics; safety; tolerability and immunogenicity for the switched and continued treatment groups. RESULTS: Equivalent efficacy between GP2017 and ref-ADMB was confirmed for the primary (66·8% and 65·0%, respectively; 95% CI -7·46 to 11·15) and key secondary end points (-60·7% and -61·5%, respectively; 95% CI -3·15 to 4·84). PASI improved over time and was similar between treatment groups at week 16, and the switched and continued groups from weeks 17 to 51. There were no relevant safety or immunogenicity differences between GP2017 and ref-ADMB at week 16, or the switched and continued groups from weeks 17 to 51. No hypersensitivity to adalimumab was reported upon switching. CONCLUSIONS: Following the demonstration of GP2017 biosimilarity to ref-ADMB, switching up to four times between GP2017 and ref-ADMB had no detectable impact on efficacy, safety or immunogenicity.

A novel vaccine (Zostavax) to prevent herpes zoster.

Varicella-zoster virus is the causal agent of varicella and herpes zoster (HZ) in humans. HZ results from reactivation of latent varicella-zoster virus (VZV) within the sensory ganglia. The incidence and severity of HZ increase with advancing age; more than half of all persons in whom HZ develops are older than 60 years. The most frequent debilitating complication is postherpetic neuralgia, a neuropathic pain syndrome that persists or develops after the dermatomal rash has healed, and can be prolonged and disabling. There are many limitations of the current therapies for HZ and postherpetic neuralgia. A live attenuated VZV vaccine has been developed and recently approved by the United States Food and Drug Administration (FDA) and the European Union for the prevention of HZ in individuals 60 years of age and older. In a randomized, double-blind, placebo-controlled trial 38,546 adults of 60 years of age or older, the use of the HZ vaccine reduced the burden of illness due to HZ by 61.1% (P<0.001), reduced the incidence of postherpetic neuralgia by 66.5% (P<0.001), and reduced the incidence of HZ by 51.3% (P<0.001). In this review, the authors will discuss the history of the use of the varicella vaccine in children, and the subsequent development of the new HZ vaccine.

Oxygen deprivation-induced injury to isolated rabbit kidney tubules.

The utility of freshly isolated suspensions of rabbit tubules enriched in proximal segments for studying the pathogenesis of oxygen deprivation-induced renal tubular cell injury was evaluated. Oxygenated control preparations exhibited very good stability of critical cell injury-related metabolic parameters including oxygen consumption, cell cation homeostasis, and adenine nucleotide metabolism for periods in excess of 2 h. Highly reproducible models of oxygen deprivation-induced injury and recovery were developed and alterations of injury-related metabolic parameters in these models were characterized in detail. When oxygen deprivation was produced under hypoxic conditions, tubules sustained widespread lethal cell injury and associated metabolic alterations within 15-30 min. However, when oxygen deprivation was produced under simulated ischemic conditions, tubules tolerated 30-60 min with only moderate amounts of lethal cell injury occurring, a situation similar to that seen with ischemia in vivo. Like ischemia in vivo, simulated ischemia in vitro was characterized by a fall in pH during oxygen deprivation. No such fall in pH occurred in the hypoxic model. To test whether this fall in pH could contribute to the protection seen during simulated ischemia in vitro, tubules were subjected to hypoxia at medium pHs ranging from 7.45 to 6.41. Striking protection from hypoxic injury was seen as pH was reduced with maximal protection occurring in tubules made hypoxic at pHs below 7.0. Measurements of injury-associated metabolic parameters suggested that the protective effect of reduced pH may be mediated by pH-induced alterations of tubule cell Ca++ metabolism. This study has, thus, defined and characterized in detail a new and extremely versatile model system for the study of oxygen deprivation-induced cell injury in the kidney and has established that pH alterations play a major role in modulating such injury.

Cytosolic-free calcium increases to greater than 100 micromolar in ATP-depleted proximal tubules.

Previous studies have shown that cytosolic-free Ca2+ (Caf) increases to at least low micromolar concentrations during ATP depletion of isolated kidney proximal tubules. However, peak levels could not be determined precisely with the Ca2+-sensitive fluorophore, fura-2, because of its high affinity for Ca2+. Now, we have used two low affinity Ca2+ fluorophores, mag-fura-2 (furaptra) and fura-2FF, to quantitate the full magnitude of Caf increase. Between 30 and 60 min after treatment with antimycin to deplete ATP in the presence of glycine to prevent lytic plasma membrane damage, Caf measured with mag-fura-2 exceeded 10 microM in 91% of tubules studied and 68% had increases to greater than 100 microM. Caf increases of similar magnitude that were dependent on influx of medium Ca2+ were also seen using the new low Ca2+ affinity, Mg2+-insensitive, fluorophore fura-2FF in tubules depleted of ATP by hypoxia, and these increases were reversed by reoxygenation. Total cell Ca2+ levels in antimycin-treated or hypoxic tubules did not change, suggesting that mitochondria were not buffering the increased Caf during ATP depletion. Considered in the context of the high degree of structural preservation of glycine-treated tubule cells during ATP depletion and the commonly assumed Ca2+ requirements for phospholipid hydrolysis, actin disassembly, and Ca2+-mediated structural damage, the remarkable elevations of Caf demonstrated here suggest an unexpected resistance to the deleterious effects of increased Caf during energy deprivation in the presence of glycine.

Calcium is a competitive inhibitor of gentamicin-renal membrane binding interactions and dietary calcium supplementation protects against gentamicin nephrotoxicity.

The divalent cations, Ca++ and Mg++, are known to competitively inhibit a large number of aminoglycoside-membrane interactions, so that Ca++ prevents both the neurotoxic and ototoxic effects of these antibiotics acutely in vitro. Since gentamicin-induced plasma and subcellular membrane damage appear to be critical pathogenetic events in gentamicin nephrotoxicity, Ca++ may play a similar protective role in gentamicin-induced acute renal failure. To test this possibility in vivo, rats (group 2) were given a 4% calcium (in the form of CaCO3) supplemented diet to increase delivery of Ca++ to the kidney and administered single daily subcutaneous injections of gentamicin, 100 mg/kg, for 10 d. Compared with a simultaneously studied group (group 1) of rats receiving identical gentamicin dosages and normal diets, Ca++ supplementation ameliorated gentamicin-induced acute renal failure. After 10 doses of gentamicin, blood-urea nitrogen values in group 1 averaged 213 +/- 15 (SE) and 25 +/- 3 (P less than 0.001) in group 2. The progressive decline in renal excretory function, as measured by BUN, in group 1 animals was accompanied by simultaneous declines in renal cortical mitochondrial function and elevations in renal cortex and mitochondrial Ca++ content, quantitative indices of the degree of renal tubular cell injury. Oral Ca++ loading markedly attenuated these gentamicin-induced derangements. After eight and 10 doses of gentamicin, mitochondria isolated from the renal cortex of group 2 rats had significantly higher rates of respiration supported by pyruvate-malate, succinate and N,N,N',N'-tetramethyl-p-phenyldiamine-ascorbate, higher rates of dinitrophenol-uncoupled respiration and greater acceptor control ratios than those measured in mitochondria isolated from the renal cortex of group 1 animals. Similarly, after 8 and 10 doses, renal cortex and renal cortical mitochondrial Ca++ content of group 2 was significantly lower than values observed in group 1. Thus, dietary calcium supplementation significantly protected against gentamicin-induced renal tubular cell injury and, consequently, gentamicin-induced acute renal failure. The mechanism for this protective effect of Ca++ may relate to the manner in which this polycationic antibiotic interacts with anionic sites, primarily the acidic phospholipids of renal membranes. In this regard, Ca++ was found to be a competitive inhibitor both of 125I-gentamicin binding to renal brush border membranes, the initial site of interaction between gentamicin and renal proximal tubule cells, with a composite inhibition constant (Ki) of 12 mM and of 125I-gentamicin binding to phosphatidic acid, an important membrane acidic phosph

Role of increased cytosolic free calcium in the pathogenesis of rabbit proximal tubule cell injury and protection by glycine or acidosis.

To assess the role of increased cytosolic free calcium (Caf) in the pathogenesis of acute proximal tubule cell injury and the protection afforded by exposure to reduced medium pH or treatment with glycine, fura-2-loaded tubules were studied in suspension and singly in a superfusion system. The Ca2+ ionophore, ionomycin, increased Caf to micromolar levels and rapidly produced lethal cell injury as indicated by loss of lactate dehydrogenase to the medium by suspended tubules and accelerated leak of fura and failure to exclude Trypan blue by superfused tubules. Decreasing medium Ca2+ to 100 nM prevented the ionomycin-induced increases of Caf and the injury. Reducing medium pH from 7.4 to 6.9 or adding 2 mM glycine to the medium also prevented the cell death, but did not prevent the increase of Caf to micromolar levels. Cells treated with 1799, an uncoupler of oxidative phosphorylation which produced severe adenosine triphosphate (ATP) depletion, did not develop increases of Caf until just before loss of viability. Preventing these increases of Caf with 100 nM Ca2+ medium did not protect 1799-treated cells. Reduced pH and glycine protected 1799-treated cells without ameliorating the increases of Caf. These data demonstrate the toxic potential of increased Caf in the proximal tubule and show that Caf does sharply increase prior to loss of viability in an ATP depletion model of injury, but this increase does not necessarily contribute to the outcome. The potent protective actions of decreased pH and glycine allow the cells to sustain increases of Caf to micromolar levels in spite of severe, accompanying cellular ATP depletion without developing lethal cell injury.

Cytoprotective effects of glycine and glutathione against hypoxic injury to renal tubules.

Roles for both the tripeptide, GSH, and individual amino acids in modifying the cellular response to oxygen deprivation-induced injury have been suggested by prior work in kidney and other tissues, but the precise interrelationships have not been clearly defined. We have studied the effects of GSH, its component amino acids, and related compounds on the behavior of isolated renal proximal tubules in a well characterized model of hypoxic injury in vitro. GSH, the combination of cysteine, glutamate, and glycine and glycine alone, when present in the medium during 30 min hypoxia, a duration sufficient to produce extensive irreversible injury in untreated tubules, were protective. Significant effects were detected at 0.25 mM concentrations of the reagents, and protection was nearly complete at concentrations of 1 mM and above. Glutamate and cysteine alone were not protective. The exogenous GSH added to the tubule suspensions was rapidly degraded to its component amino acids. Treatment of tubules with GSH or cysteine, but not glycine, increased intracellular GSH levels. Oxidized GSH was protective. Serine, N-(2-mercaptopropionyl)-glycine, and a panel of agents known to modify injury produced by reactive oxygen metabolites were without benefit. These observations identify a novel and potent action of glycine to modify the course of hypoxic renal tubular cell injury. This effect is independent of changes in cellular GSH metabolism and appears to be unrelated to alterations of cell thiols or reactive oxygen metabolites. Further elucidation of its mechanism may provide insight into both the basic pathophysiology of oxygen deprivation-induced cell injury and a practical way to ameliorate it.

Energy thresholds that determine membrane integrity and injury in a renal epithelial cell line (LLC-PK1). Relationships to phospholipid degradation and unesterified fatty acid accumulation.

This study related ATP levels with membrane damage, lipid abnormalities, and cell death in energy-depleted LLC-PK1 cells. Oxidative phosphorylation was inhibited by antimycin A, and glycolysis was regulated by graded glucose deprivation to achieve stepwise ATP depletion. Over a range of ATP levels down to approximately equal to 5% of normal, over 5 h, cells were altered only minimally, or injured reversibly. Such cells maintained mitochondrial potential, and retained more K+ than cells without an energy source. Over the same duration, cells without an energy source were lethally injured. Treatment with antimycin induced increments of triglycerides and decreases of phospholipids. With severe ATP depletion (approximately equal to 5-10% of normal after 5 h), decrease of phospholipids was marked. Cells in which ATP was not measurable (or was less than 5% of normal) showed comparable phospholipid declines but, in addition, showed massive and progressive increase of unesterified fatty acids. The results identified a low threshold of ATP, at best 5-10% of normal, which preserved viability in LLC-PK1 cells despite major loss of membrane phospholipids. This threshold also determined the ability of cells to maintain their normally low levels of unesterified fatty acids. Failure of energy-dependent mechanisms that normally metabolize unesterified fatty acids may be a correlate of the extent of energy depletion that determines lethal injury.

Mechanisms of cell death in hypoxia/reoxygenation injury.

Investigation of death pathways during cell injury in vivo caused by ischemia and reperfusion is of clinical importance, but technically difficult. Heterogeneity of cell types, differences between organ systems, diversity of death paradigms and exacerbation of tissue damage caused by inflammation are only some of the variables that need to be taken into account. With respect to the identification of necrosis and apoptosis in affected organs, technical issues related to preparation artifacts, occurrence of internucleosomal DNA cleavage in necrotic as well as apoptotic cells and other overlaps in death pathways bear consideration. In that caspase independent as well as caspase dependent processes cause cell death and that caspase inhibitors can act as anti-inflammatory agents, evaluation of ischemic death mechanisms in parenchymal cells needs to be performed with caution. When the effects of inflammation are removed by appropriate in vitro studies using purified or cultured cells, several mitochondrial factors that lead to cell death can be studied. Substantial evidence exists for the participation of electron transport defects, mitochondrial permeability transitions (MPT) and release of cytochrome c from mitochondria, effected by pro-apoptotic proteins such as Bax. The anti-apoptotic protein Bcl-2 exerts an overriding protective role in this type of injury by preserving mitochondrial structure and function. In contrast, caspase inhibitors cannot offer long-term protection to ischemically injured parenchymal cells regardless of how effectively they can inhibit apoptotic events, if the cells have suffered permanent mitochondrial damage impairing respiration.

Role of hypoxia-induced Bax translocation and cytochrome c release in reoxygenation injury.

We investigated mechanisms of cell death during hypoxia/reoxygenation of cultured kidney cells. During glucose-free hypoxia, cell ATP levels declined steeply resulting in the translocation of Bax from cytosol to mitochondria. Concurrently, there was cytochrome c release and caspase activation. Cells that leaked cytochrome c underwent apoptosis after reoxygenation. ATP depletion induced by a mitochondrial uncoupler resulted in similar alterations even in the presence of oxygen. Moreover, inclusion of glucose during hypoxia prevented protein translocations and reoxygenation injury by maintaining intracellular ATP. Thus, ATP depletion, rather than hypoxia per se, was the cause of protein translocations. Overexpression of Bcl-2 prevented cytochrome c release and reoxygenation injury without ameliorating ATP depletion or Bax translocation. On the other hand, caspase inhibitors did not prevent protein translocations, but inhibited apoptosis during reoxygenation. Nevertheless, they could not confer long-term viability, since mitochondria had been damaged. Omission of glucose during reoxygenation resulted in continued failure of ATP production, and cell death with necrotic morphology. In contrast, cells expressing Bcl-2 had functional mitochondria and remained viable during reoxygenation even without glucose. Therefore, Bax translocation during hypoxia is a molecular trigger for cell death during reoxygenation. If ATP is available during reoxygenation, apoptosis develops; otherwise, death occurs by necrosis. By preserving mitochondrial integrity, BCL-2 prevents both forms of cell death and ensures cell viability.

P element-mediated in vivo deletion analysis of white-apricot: deletions between direct repeats are strongly favored.

We have isolated and characterized deletions arising within a P transposon, P[hswa], in the presence of P transposase. P[hswa] carries white-apricot (wa) sequences, including a complete copia element, under the control of an hsp70 promoter, and resembles the original wa allele in eye color phenotype. In the presence of P transposase, P[hswa] shows a high overall rate (approximately 3%) of germline mutations that result in increased eye pigmentation. Of 234 derivatives of P[hswa] with greatly increased eye pigmentation, at least 205 carried deletions within copia. Of these, 201 were precise deletions between the directly repeated 276-nucleotide copia long terminal repeats (LTRs), and four were unique deletions. High rates of transposase-induced precise deletion were observed within another P transposon carrying unrelated 599 nucleotide repeats (yeast 2 mu FLP; recombinase target sites) separated by 5.7 kb. Our observation that P element-mediated deletion formation occurs preferentially between direct repeats suggests general methods for controlling deletion formation.

Distribution of gentamicin among subcellular fractions from rat renal cortex.

A substantial amount of data is available to suggest that lysosomal sequestration of aminoglycoside antibiotics plays a role in the pathogenesis of aminoglycoside-induced renal tubule cell injury; however, relatively little information is available on the subcellular distribution of aminoglycosides in the kidney during treatment protocols of the type that ultimately go on to produce extensive lethal renal tubule cell injury and acute renal failure in experimental animals. This study assessed the distribution of gentamicin and subcellular membranes on a discontinuous sucrose density gradient after in vivo exposure of rats to four daily 100 mg/kg doses of gentamicin as compared to in vitro exposure of normal rat renal cortex to gentamicin during tissue homogenization at drug levels comparable to those seen after in vivo treatment. After both in vivo and in vitro exposure, major localization of gentamicin, the lysosomal marker enzyme N-acetyl-beta-D-glucosaminidase (NAG), and the endoplasmic reticulum marker enzyme NADPH-cytochrome c reductase, occurred in a very light membrane fraction. Within this membrane fraction, gentamicin was more closely associated with the NAG than with the NADPH-cytochrome c reductase. The results could not be explained by complete lysosomal disruption during subcellular fractionation after in vivo gentamicin. These data provide additional insights into both the possibilities for subcellular interactions of aminoglycosides in the kidney, and into the methodology required to optimally assess such interactions.

Molecular diagnosis of lymphocytic infiltrates of the skin.

BACKGROUND: Advances in our understanding of the molecular genetics of lymphocyte antigen receptors (B-cell immunoglobulin and T-cell antigen receptor), have led to the application of molecular biologic techniques to molecularly characterize lymphocytic infiltrates of the skin. Molecular diagnosis refers to the application of these techniques as a diagnostic aid in the clinicopathologic evaluation of cutaneous lymphocytic infiltrates. OBSERVATION: Molecular studies have clinical application in the determination of lineage and detection of retroviruses in cutaneous lymphoid neoplasms, distinguishing between lymphoproliferative and reactive infiltrates, and staging and monitoring response to therapy in cutaneous T-cell lymphoma. Southern blot analysis of immunoglobulin and T-cell antigen receptor gene rearrangements may fail to aid the clinician in establishing a diagnosis of a cutaneous malignancy due to the limits of detection sensitivity in minimally infiltrated lesions (eg, parapsoriasis and patch-stage mycosis fungoides) or the still uncertain prognostic significance of clonality in benign cutaneous diseases (eg, follicular mucinosis, pityriasis lichenoides et varioliformis acuta, lymphomatoid papulosis, and cutaneous lymphoid hyperplasia). CONCLUSIONS: Molecular studies have enormous research value, providing new means to explore the pathogenesis and clonal evolution of lymphoproliferative skin diseases. Presently, however, they have limited applications as an independent diagnostic tool. As our understanding of the clinical and biologic significance of the molecular detection of clonal lymphocyte populations in the skin expands and as the application of polymerase chain reaction amplification provides us with greater detection sensitivity and specificity, the clinical utility of molecular diagnosis of lymphocytic infiltrates of the skin will be enhanced.

Viral folliculitis. Atypical presentations of herpes simplex, herpes zoster, and molluscum contagiosum.

BACKGROUND: Viral folliculitis is an infrequently reported entity. The patients described herein were seen over a 12-year period of practice in a referral dermatologic setting. The cases involve a variety of viral infections limited to the hair follicle. OBSERVATIONS: We describe 5 patients with a variety of viral folliculitides: 2 with herpetic sycosis caused by herpes simplex; 1 with herpex simplex folliculitis (this patient also had human immunodeficiency virus); 1 with herpes zoster without blisters; and 1 with molluscum contagiosum. CONCLUSIONS: These 5 cases demonstrate that viral folliculitis has varied causes and presentations. Clinicians should consider viral agents in the differential diagnosis of superficial infectious folliculitis, especially in cases that are refractory to antibacterial or antifungal therapy.

The effect of gentamicin on calcium uptake by renal mitochondria.

The effect of the nephrotoxic aminoglycoside antibiotic, gentamicin, on calcium uptake by renal cortical mitochondria was assessed in vitro. Gentamicin was found to be a competitive inhibitor of mitochondrial Ca++ uptake. This effect displayed a dose response with a Ki of 233 microM and occurred at gentamicin concentrations below those that inhibit mitochondrial electron transport. These results further demonstrate the potential for gentamicin to alter membrane function and thereby contribute to toxic cell injury via its interactions with divalent cations.

Hydrogen peroxide-induced cell and tissue injury: protective effects of Mn2+.

Recent evidence indicates that under in vitro conditions, superoxide anion and hydrogen peroxide (H2O2) are unstable in the presence of manganese ion (Mn2+). The current studies show that in the presence of Mn2+, H2O2-mediated injury of endothelial cells is greatly attenuated. A source of bicarbonate ion and amino acid is required for Mn2+ to exert its protective effects. Injury by phorbol ester-activated neutrophils is also attenuated under the same conditions. EDTA reverses the protective effects. Acute lung injury produced in vivo in rats by intratracheal instillation of glucose-glucose oxidase is almost completely blocked in rats treated with Mn2+ and glycine. Conversely, treatment of rats with EDTA, a chelator of Mn2+, markedly accentuates lung injury caused by glucose-glucose oxidase. These data are consistent with the findings of others that Mn2+ can facilitate direct oxidation of amino acids with concomitant H2O2 disproportionation. This could form the basis of a new therapeutic approach against oxygen radical-mediated tissue injury.

Viral folliculitis.

Viral folliculitis is an infrequently reported entity. We describe two patients with viral folliculitides, including a case of herpetic sycosis caused by herpes simplex (HSV) and a case of herpes zoster (HZ) without blisters. Clinicians should consider viral etiologies in the differential diagnosis of superficial infectious folliculitis, especially those cases refractory to antibacterial or antifungal therapy.

Evaluation of pigmented lesions of the nail unit.

Acquired pigmentary changes of the nail are secondary to a number of etiologies. These include nail matrix nevi; physical induction secondary to trauma; malignant melanoma; nutritional deficiencies; inflammation secondary to lichen planus; endocrine causes such as Addison's disease; or secondary to bacterial, fungal, or viral infections. The most important task faced by clinicians is to distinguish benign from malignant etiologies of nail pigmentation. We will briefly review the various entities that can yield dyspigmentation and their differentiation from melanoma of the nail.

The ocular manifestations of rosacea.

The ocular manifestations of rosacea are commonly nonspecific and variable. The etiology of the inflammation is unknown and there is no diagnostic test for the disease. Ocular rosacea is often underdiagnosed, despite the potential for serious sight-threatening sequelae. When evaluating patients with rosacea, dermatologists should obtain a careful history of eye complaints and examine the eyelid margins thoroughly. Treatment is aimed at controlling symptoms and is multifaceted. The foundation of treatment is good lid hygiene and oral tetracyclines. Those patients with moderate-to-severe ocular findings will benefit from a multidisciplinary approach, including evaluation by an ophthalmologist.

A review of the 308-nm excimer laser in the treatment of psoriasis.

The 308-nm excimer laser is a new modality for the treatment of psoriasis. With the 308-nm UVB radiation generated by this laser, it is possible to clear psoriasis with as little as one treatment and to have a moderately long remission. In contrast to traditional phototherapy techniques, this handheld excimer laser UVB therapy is selectively directed toward lesional skin, thus sparing the surrounding normal skin from unnecessary radiation exposure. This modality may offer a new alternative in the treatment of limited psoriasis and other inflammatory diseases.