The metabolic syndrome in untreated schizophrenia patients: prevalence and putative mechanisms.

The Metabolic Syndrome (MetS) is a constellation of commonly coexisting clinical markers. It is well established that MetS is more prevalent in schizophrenic (SCZ) patients medicated with atypical antipsychotics, however, questions still exist over whether schizophrenia itself can contribute directly to metabolic dysfunction. We evaluated the antipsychotic-independent link between MetS and schizophrenia, by conducting a systematic literature search. Twelve papers were identified, from which 893 patients were evaluated. The mean prevalence of MetS was 10.8%, suggesting its incidence is not increased. However, some aspects of MetS may be increased, such as diabetes. Hypothalamic-pituitary axis dysfunction, sympathetic nervous system dysfunction, proinflammatory states and several genetic mutations have been implicated in the observed metabolic dysregulation in schizophrenic patients, however much controversy exists in this area. The huge cardiovascular burden makes it crucial to establish the causes and optimal management of MetS in schizophrenia.

Semiconductor diode laser device adjuvanting intradermal vaccine.

A brief exposure of skin to a low-power, non-tissue damaging laser light has been demonstrated to augment immune responses to intradermal vaccination. Both preclinical and clinical studies show that this approach is simple, effective, safe and well tolerated compared to standard chemical or biological adjuvants. Until now, these laser exposures have been performed using a diode-pumped solid-state laser (DPSSL) devices, which are expensive and require labor-intensive maintenance and special training. Development of an inexpensive, easy-to-use and small device would form an important step in translating this technology toward clinical application. Here we report that we have established a handheld, near-infrared (NIR) laser device using semiconductor diodes emitting either 1061, 1258, or 1301nm light that costs less than $4000, and that this device replicates the adjuvant effect of a DPSSL system in a mouse model of influenza vaccination. Our results also indicate that a broader range of NIR laser wavelengths possess the ability to enhance vaccine immune responses, allowing engineering options for the device design. This small, low-cost device establishes the feasibility of using a laser adjuvant approach for mass-vaccination programs in a clinical setting, opens the door for broader testing of this technology with a variety of vaccines and forms the foundation for development of devices ready for use in the clinic.

Anti-CCR4 monoclonal antibody enhances antitumor immunity by modulating tumor-infiltrating Tregs in an ovarian cancer xenograft humanized mouse model.

Recent studies have demonstrated that regulatory T cells (Tregs) are recruited to tumor sites where they can suppress antitumor immunity. The chemokine receptor CCR4 is expressed at high levels on functional CD4+CD25+FoxP3+ Tregs and production of the CCR4 ligand CCL22 by tumor cells and tumor-associated macrophages is associated with Treg recruitment to the tumor site. Here, we tested IgG1 and IgG4 isotypes of human anti-CCR4 mAb2-3 for their in vitro activity and in vivo capacity in a NSG mouse model bearing CCL22-secreting ovarian cancer (OvCA) xenograft to modulate Tregs and restore antitumor activity. Both mAb2-3 isotypes blocked in vitro chemoattraction of Tregs to CCL22-secreting OvCA cells. However, they differed in their in vivo mode of action with IgG1 causing Treg depletion and IgG4 blocking migration to the tumors. Primary T cells that were primed with OvCA-pulsed dendritic cells (DCs) demonstrated INFγ secretion that could be enhanced through Treg depletion by mAb2-3. Humanized mice reconstructed with allogeneic tumor-primed T cells (TP-T) were used to evaluate the restoration of OvCA immunity by depletion or blockade of Tregs with mAb2-3. We observed that IgG1 was more potent than IgG4 in inhibiting tumor growth. Mechanism studies demonstrated that mAb2-3 treatment lead to inhibition of IL-2 binding to its receptor. Further studies showed that mAb2-3 induced CD25 shedding (sCD25) from Tregs which lead to a decrease in IL-2-dependent survival. Together, the results demonstrate that mAb2-3 is an agonist antibody that can restore anti-OvCA immunity through modulation of Treg activity.

Indispensable or intolerable? Methotrexate in patients with rheumatoid and psoriatic arthritis: a retrospective review of discontinuation rates from a large UK cohort.

Methotrexate (MTX) has become the first-line treatment for rheumatoid (RA) and psoriatic arthritis (PsA); however, few studies have focused on its tolerability. The objective of our analyses was to study RA and PsA patients in whom MTX was discontinued, the reasons for this and the duration of MTX treatment prior to withdrawal. A retrospective electronic database review was undertaken to identify all patients who had received MTX for RA or PsA. Patients who had discontinued MTX were then identified, and the reasons for this were categorised. The duration of MTX treatment was assessed in those who had stopped treatment due to intolerability. A total of 1,257 patients who had received MTX were identified [762 (61 %) RA and 193 (15 %) PsA]. MTX had been stopped in 260 (34 %) patients with RA and 71 (36 %) patients with PsA most commonly due to gastrointestinal intolerability. The median duration of MTX treatment was 10 months in both groups, mean duration 21 and 18.6 months in RA and PsA groups, respectively. Overall, one third of patients with RA and PsA stop MTX most commonly due to poor tolerability. In the context of chronic disease, the median duration of treatment is short (10 months). Our analysis did not include patients who suffer from side effects but continue therapy; thus, the magnitude of the problem may be substantially greater therefore as poor tolerability impacts treatment adherence.

Near-infrared laser adjuvant for influenza vaccine.

Safe and effective immunologic adjuvants are often essential for vaccines. However, the choice of adjuvant for licensed vaccines is limited, especially for those that are administered intradermally. We show that non-tissue damaging, near-infrared (NIR) laser light given in short exposures to small areas of skin, without the use of additional chemical or biological agents, significantly increases immune responses to intradermal influenza vaccination without augmenting IgE. The NIR laser-adjuvanted vaccine confers increased protection in a murine influenza lethal challenge model as compared to unadjuvanted vaccine. We show that NIR laser treatment induces the expression of specific chemokines in the skin resulting in recruitment and activation of dendritic cells and is safe to use in both mice and humans. The NIR laser adjuvant technology provides a novel, safe, low-cost, simple-to-use, potentially broadly applicable and clinically feasible approach to enhancing vaccine efficacy as an alternative to chemical and biological adjuvants.