Practical management of suspected hypersensitivity reactions to anti-tuberculosis drugs.

Tuberculosis (TB) is the commonest cause of death by a single infectious agent globally and ranks amongst the top ten causes of global mortality. The incidence of TB is highest in Low-Middle Income countries (LMICs). Prompt institution of, and compliance with, therapy are cornerstones for a favourable outcome in TB and to mitigate the risk of multiple drug resistant (MDR)-TB, which is challenging to treat. There is some evidence that adverse drug reactions (ADRs) and hypersensitivity reactions (HSRs) to anti-TB drugs occur in over 60% and 3%-4% of patients respectively. Both ADRs and HSRs represent significant barriers to treatment adherence and are recognised risk factors for MDR-TB. HSRs to anti-TB drugs are usually cutaneous and benign, occur within few weeks after commencement of therapy and are likely to be T-cell mediated. Severe and systemic T-cell mediated HSRs and IgE mediated anaphylaxis to anti-TB drugs are relatively rare, but important to recognise and treat promptly. T-cell-mediated HSRs are more frequent amongst patients with co-existing HIV infection. Some patients develop multiple sensitisation to anti-TB drugs. Whilst skin tests, patch tests and in vitro diagnostics have been used in the investigation of HSRs to anti-TB drugs, their predictive value is not established, they are onerous, require specialist input of an allergist and are resource-dependent. This is compounded by the global, unmet demand for allergy specialists, particularly in low-income countries (LICs)/LMICs and now the challenging circumstances of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic. This narrative review provides a critical analysis of the limited published evidence on this topic and proposes a cautious and pragmatic approach to optimise and standardise the management of HSRs to anti-TB drugs. This includes clinical risk stratification and a dual strategy involving sequential re-challenge and rapid drug desensitisation. Furthermore, a concerted international effort is needed to generate real-time data on ADRs, HSRs, safety and clinical outcomes of these interventions.

Indolamine 2,3-dioxygenase is expressed in the CNS and down-regulates autoimmune inflammation.

The tryptophan (trp)-catabolizing enzyme indolamine 2,3-dioxygenase (IDO) is induced by the T helper 1 (Th 1) cytokine IFN-gamma during infections in various tissues including the brain. Recent studies demonstrated an immune modulatory function of this enzyme, since IDO-mediated depletion of trp hinders T cell proliferation, while its inhibition by 1-methyl-tryptophan (1-Mt) induces breakdown of immune tolerance in the placenta, leading to rejection of allogeneic concepti. Here, we tested IDO expression and function during experimental autoimmune encephalomyelitis (EAE) actively induced in adult SJL mice by immunization with PLP139-151. IDO activity (determined by HPLC analysis of the kynurenine/tryptophan ratio) was increased in the spleen during the preclinical phase, and within the brain and spinal cord at the onset of symptoms. Immunocytochemistry revealed macrophages/activated microglia expressing IDO during EAE and in vitro experiments confirmed IDO induction in microglia upon IFN-gamma treatment with synergistic effects of TNF-alpha. Inhibition of IDO by systemic administration of 1-Mt at clinical onset significantly exacerbated disease scores. From these data, it is tempting to speculate that IFN-gamma from encephalitogenic Th 1 cells induces local IDO expression, thereby initiating a negative feedback loop which may underlie the self-limitation of autoimmune inflammation during EAE and multiple sclerosis.

Caspase-3-mediated cleavage of amyloid precursor protein and formation of amyloid Beta peptide in traumatic axonal injury.

Immunohistochemical studies demonstrate accumulation of the beta-amyloid precursor protein (APP) within injured axons following traumatic brain injury (TBI). Despite such descriptions, little is known about the ultimate fate of accumulating APP at sites of traumatic axonal injury (TAI). Recently, caspase-3-mediated cleavage of APP and subsequent Abeta deposition was linked to apoptotic neuronal death pathways in hippocampal neurons following ischemic and excitotoxic brain injury. Given that (1) APP is known to accumulate within traumatically injured axons, (2) caspase-3 activation has been demonstrated in traumatic axonal injury (TAI), and (3) recent studies have identified a caspase-3 cleavage site within APP, we initiated the current investigation to determine whether caspase-3-mediated cleavage of APP occurs in TAI. We further assessed whether these events were found in relation to Abeta peptide formation. To this end, we employed antibodies targeting APP, the caspase-3-mediated breakdown product of APP proteolysis, and the Abeta peptide. Rats were subjected to impact acceleration TBI (6 h to 10 days survival), and their brains were processed for single-label bright field and multiple double-label immunofluorescent paradigms using the above antibodies. By 12 h postinjury, caspase-3-mediated APP proteolysis (CMAP) was demonstrated within the medial lemniscus (ML) and medial longitudinal fasciculus (MLF) in axons undergoing TAI, identified by their concomitant APP accumulation. Immunoreactivity for CMAP persisted up to 48 h postinjury in the ML and MLF, but was notably reduced by 10 days following injury. Further, CMAP was colocalized with Abeta formation in foci of TAI. The current study demonstrates that caspase-3 cleavage of APP occurs in TAI and is associated with formation of Abeta peptide. These findings are of interest given recent epidemiological studies supporting an association between TBI and later risk for AD development.

Dose-response of cyclosporin A in attenuating traumatic axonal injury in rat.

Cyclosporin A has emerged as a promising therapeutic agent in traumatic brain injury (TBI), although its precise neuroprotective mechanism is unclear. Cyclosporin A, given as a single-dose intrathecal bolus, has previously been shown to attenuate mitochondrial damage and reduce axonal injury in experimental TBI. We assessed the effect of a range of intravenous cyclosporin A doses upon axonal injury attenuation to determine the ideal dose. Rats were subjected to experimental TBI and given one of five intravenous doses of cyclosporin A. At 3 h post-injury, brains were processed for brain tissue cyclosporin A concentration. In a second set of animals, at 24 h postinjury, brains were processed for amyloid precursor protein immunoreactivity, a widely used marker of axonal injury. Intravenous administration produced therapeutic levels of cyclosporin A in brain parenchyma. Higher concentrations were achieved with equivalent doses given intrathecally; this is consistent with the reported poor blood-brain barrier permeability of cyclosporin A. Cyclosporin A 10 mg/kg i.v. produced the greatest degree of neuroprotection against diffuse axonal injury; cyclosporin A 50 mg/kg i.v. was toxic. Intravenous cyclosporin A administration achieves therapeutic levels in brain parenchyma and 10 mg/kg is the most effective dose in attenuating axonal damage after traumatic brain injury.

Tolerogenic effect of fiber tract injury: reduced EAE severity following entorhinal cortex lesion.

Despite transient, myelin-directed adaptive immune responses in regions of fiber tract degeneration, none of the current models of fiber tract injuries evokes disseminated demyelination, implying effective mechanisms maintaining or re-establishing immune tolerance. In fact, we have recently detected CD95L upregulation accompanied by apoptosis of leukocytes in zones of axonal degeneration induced by entorhinal cortex lesion (ECL), a model of layer-specific axonal degeneration. Moreover, infiltrating monocytes readily transformed into ramified microglia exhibiting a phenotype of immature (CD86+/CD80-) antigen-presenting cells. We now report the appearance of the axonal antigen neurofilament-light along with increased T cell apoptosis and enhanced expression of the pro-apoptotic gene Bad in cervical lymph nodes after ECL. In order to test the functional significance of such local and systemic depletory/regulatory mechanisms on subsequent immunity to central nervous system antigens, experimental autoimmune encephalomyelitis was induced by proteolipid protein immunization 30 days after ECL. In three independent experiments, we found significantly diminished disease scores and infiltrates in lesioned compared to sham-operated SJL mice. This is consistent with a previous meta-statistical analysis (Goodin et al. in Neurology 52:1737-1745, 1999) rejecting the O-hypothesis that brain trauma causes or exacerbates multiple sclerosis. Conversely, brain injuries may involve long-term tolerogenic effects towards brain antigens.

Inflammatory response after neurosurgery.

Investigation into the inflammatory response in the central nervous system (CNS) is a rapidly growing field, and a vast amount of information on this topic has accumulated over the past two decades. Inflammation is a particularly interesting issue in the (traditionally non-regenerating) CNS, owing to its dual role in worsening or improving regeneration and functional outcome in certain circumstances. This paper reviews the current literature on the interactions between the immune system and the CNS in physiological and pathological states. The first part will provide an overview of the cellular and molecular components of CNS inflammation, this being followed by a discussion of the concept of systemic immunodepression after neurotrauma and neurosurgery. Finally, the delicate balance of immune responses in the CNS, with an emphasis on the beneficial effects of inflammation and possible therapeutic options, will be discussed.

Impaired axonal transport and altered axolemmal permeability occur in distinct populations of damaged axons following traumatic brain injury.

Traumatic axonal injury (TAI) evolves within minutes to hours following traumatic brain injury (TBI). Previous studies have identified axolemmal disruption and impaired axonal transport (AxT) as key mechanisms in the evolution of TAI. While initially hypothesized that axolemmal disruption culminates in impaired AxT, previous studies employed single-label methodologies that did not allow for a full determination of the spatial-temporal relationships of these two events. To explore directly the relationship between impaired AxT and altered axolemmal permeability, the current investigation employed 40, 10, and 3 kDa fluorescently conjugated dextrans as markers of axolemmal integrity, with antibodies targeting the anterogradely transported amyloid precursor protein (APP) utilized as a marker of impaired AxT. Rats underwent impact acceleration TBI and were intrathecally administered 40 kDa, 40 + 10 kDa or 40 + 3 kDa fluorescently tagged dextrans, with brains subsequently prepared for APP immunofluorescence. Brainstem corticospinal tracts (CSpT), medial lemnisci (ML), and medial longitudinal fasciculi were examined for evidence of TAI. APP and all dextrans consistently localized to distinct classes of TAI. Dextrans were noted as early as 5 min following injury within axonal segments demonstrating an irregular/tortuous appearance, and were seen within thin and elongate/vacuolated axons by 30 min-6 h following injury. APP, first noted within swollen axons at 30 min following injury, was found within progressively swollen axons that showed no dextran colocalization within 3 h of injury. However, by 6 h, dextrans colocalized in disconnected axonal bulbs. At this time-point, dextrans also persisted within single-labeled, highly vacuolated/thin, and elongate axons. These studies confirm that axolemmal disruption and impaired AxT occur as distinct non-related events early in the pathogenesis of TAI. Further, these studies provide evidence that the process of impaired axonal transport and subsequent axonal disconnection leads to delayed axolemmal instability, rather than proceeding as a consequence of initial axolemmal failure. This finding underscores the need of multiple approaches to fully assess the axonal response to TBI.