Hantaviruses comprise an emerging global threat for public health, affecting about 30,000 humans annually. Infection may lead to Hantavirus pulmonary syndrome (HPS) in the Americas and hemorrhagic fever with renal syndrome (HFRS) in the Europe and Asia. Humans are spillover hosts, acquiring infection primarily through the inhalation of aerosolized excreta from infected rodents and insectivores. Risk factors for infection include involvement in outdoor activities, such as rural- and forest-related activities, peridomestic rodent presence, exposure to potentially infected dust and outdoor military training; prolonged, intimate contact with infected individuals promotes transmission of Andes virus, the only Hantavirus known to be transmitted from human-to-human. The total number of Hantavirus case reports is generally on the rise, as is the number of affected countries. Knowledge of the geographical distribution, regional incidence and associated risk factors of the disease are crucial for clinicians to suspect and diagnose infected individuals early on. Climatic, ecological and environmental changes are related to fluctuations in rodent populations, and subsequently to human epidemics. Thus, prevention may be enhanced by host-reservoir control and human exposure prophylaxis interventions, which likely have led to a dramatic reduction of human cases in China over the past decades; vaccination may also play a role in the future.
Multidrug-resistant bacteria have on overwhelming impact on human health, as they cause over 670,000 infections and 33,000 deaths annually in the European Union alone. Of these, the vast majority of infections and deaths are caused by only a handful of species—multi-drug resistant Escherichia coli, Staphylococcus aureus, Pseudomonas aeruginosa, Enterococcus spp., Acinetobacter spp. and Klebsiella pneumoniae. These pathogens employ a multitude of antibiotic resistance mechanisms, such as the production of antibiotic deactivating enzymes, changes in antibiotic targets, or a reduction of intracellular antibiotic concentration, which render them insusceptible to multiple antibiotics. The purpose of this review is to summarize in a clinical manner the resistance mechanisms of each of these 6 pathogens, as well as the mechanisms of recently developed antibiotics designed to overcome them. Through a basic understanding of the mechanisms of antibiotic resistance, the clinician can better comprehend and predict resistance patterns even to antibiotics not reported on the antibiogram and can subsequently select the most appropriate antibiotic for the pathogen in question.
Hantaviruses cause Hantavirus Pulmonary Syndrome (HPS; also called Hantavirus Cardiopulmonary Syndrome) in the Americas and Hemorrhagic Fever with Renal Syndrome (HFRS) in Asia and Europe. In Scandinavia and northern Europe, a milder form of HFRS is prevalent, termed nephropathica epidemica (NE). HPS presents with acute respiratory failure, mild-moderate renal failure, thrombocytopenia, and reactive lymphocytosis. HFRS has pronounced renal dysfunction and less prominent respiratory involvement, with thrombocytopenia and hemorrhagic findings. Both syndromes have long-term sequelae. Common symptomatology is due to underlying pathophysiology, mainly increased vascular permeability and immune activation. Laboratory and imaging markers predicting disease severity are under research, allowing for more efficient patient management. Diagnosis is presumptive, based on typical clinical findings and patient history of likely rodent exposure. Confirmation of diagnosis is by serological testing and/or RT-PCR. Treatment is mainly comprised of cardiovascular, respiratory, and renal function support, with fluid and electrolyte homeostasis being crucial components of care. In HPS, the use of extracorporeal membrane oxygenation in decompensated patients has also shown to be beneficial.
MG was found to represent an important microbial pathogen among patients presenting with symptoms of urethritis or cervicitis in Greece. Consideration of MG as cause of STD seems crucial in diagnostic algorithms and treatment strategies.
Objectives
In late July, Cyprus experienced the second epidemic wave of COVID‐19. We present the steps taken by the government and evaluate their effect on epidemic trends.
Materials
Cyprus Press and Information Office data were analysed. Using an R‐based forecasting program, two models were created to predict cases up to 01/09/2020: Model 1, which utilised data up to 09/06/2020, when airports reopened to foreign travelers with COVID‐19 screening; and Model 2, which utilised data until 24/06/2020, when screening for passengers from low‐transmission countries was discontinued.
Results
PIO data revealed no significant policy changes between 24/06/2020 and 31/07/2020. Prediction models were robust and accurate (Model 1,
R
2
= 0.999,
P
< .001; Model 2,
R
2
= 0.998,
P
< .001). By August 30th, recorded cases exceeded those predicted by Model 1 by 24.47% and by Model 2 by 20.95%, with
P
values <.001 for both cases.
Conclusions
The significant difference between recorded cases and those projected by Models 1 and 2 suggests that changes in epidemic trends may have been associated with policy changes after their respective dates. Discontinuation of major restrictions such as airport reopening, can destabilise the control of the epidemic, and may concomitantly necessitate a reevaluation of the current epidemic status. In the face of an evolving situation such as the COVID‐19 pandemic, states are forced to balance the imposing of restrictions against their impact on the economy.
bWe report the first case of cefepime-induced "red-man syndrome," which appeared 30 min following drug infusion and was confirmed with a rechallenge test. This syndrome is classically associated with vancomycin infusion and is the result of non-IgE mediated mast cell degranulation. While this adverse effect can be easily managed with drug withdrawal and antihistamine administration, it is unknown whether it can be prevented with slower cefepime infusion and preinfusion antihistamines, as is the case with vancomycin.
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