Bat coronavirus was detected positive from insectivorous bats in Krau Wildlife Reserve Forest

@#Bats are flying mammals with unique immune systems that allow them to hold many pathogens. Hence, they are recognised as the reservoir of many zoonotic pathogens. In this study, we performed molecular detection to detect coronaviruses, paramyxoviruses, pteropine orthoreoviruses and dengue viruses from samples collected from insectivorous bats in Krau Reserve Forest. One faecal sample from Rhinolophus spp. was detected positive for coronavirus. Based on BLASTN, phylogenetic analysis and pairwise alignment-based sequence identity calculation, the detected bat coronavirus is most likely to be a bat betacoronavirus lineage slightly different from coronavirus from China, Philippines, Thailand and Luxembourg. In summary, continuous surveillance of bat virome should be encouraged, as Krau Reserve Forest reported a wide spectrum of biodiversity of insectivorous and fruit bats. Moreover, the usage of primers for the broad detection of viruses should be reconsidered because geographical variations might possibly affect the sensitivity of primers in a molecular approach.

Bat coronavirus was detected positive from insectivorous bats in Krau Wildlife Reserve Forest.

Bats are flying mammals with unique immune systems that allow them to hold many pathogens. Hence, they are recognised as the reservoir of many zoonotic pathogens. In this study, we performed molecular detection to detect coronaviruses, paramyxoviruses, pteropine orthoreoviruses and dengue viruses from samples collected from insectivorous bats in Krau Reserve Forest. One faecal sample from Rhinolophus spp. was detected positive for coronavirus. Based on BLASTN, phylogenetic analysis and pairwise alignment-based sequence identity calculation, the detected bat coronavirus is most likely to be a bat betacoronavirus lineage slightly different from coronavirus from China, Philippines, Thailand and Luxembourg. In summary, continuous surveillance of bat virome should be encouraged, as Krau Reserve Forest reported a wide spectrum of biodiversity of insectivorous and fruit bats. Moreover, the usage of primers for the broad detection of viruses should be reconsidered because geographical variations might possibly affect the sensitivity of primers in a molecular approach.

Understanding the dynamics of COVID-19; implications for therapeutic intervention, vaccine development and movement control.

The COVID-19 disease is caused by the SARS-CoV-2 virus, which is highly infective within the human population. The virus is widely disseminated to almost every continent with over twenty-seven million infections and over ninety-thousand reported deaths attributed to COVID-19 disease. SARS-CoV-2 is a single stranded RNA virus, comprising three main viral proteins; membrane, spike and envelope. The clinical features of COVID-19 disease can be classified according to different degrees of severity, with some patients progressing to acute respiratory distress syndrome, which can be fatal. In addition, many infections are asymptomatic or only cause mild symptoms. As there is no specific treatment for COVID-19 there is considerable endeavour to raise a vaccine against SARS-CoV-2, in addition to engineering neutralizing antibody interventions. In the absence of an effective vaccine, movement controls of varying stringencies have been imposed. Whilst enforced lockdown measures have been effective, they may be less effective against the current strain of SARS-CoV-2, the G614 clade. Conversely, other mutations of the virus, such as the Δ382 variant could reduce the clinical relevance of infection. The front runners in the race to develop an effective vaccine focus on the SARS-Co-V-2 Spike protein. However, vaccines that produce a T-cell response to a wider range of SARS-Co-V-2 viral proteins, may be more effective. Population based studies that determine the level of innate immunity to SARS-CoV-2, from prior exposure to the virus or to other coronaviruses, will have important implications for government imposed movement control and the strategic delivery of vaccination programmes.

High-resolution endoluminal sonography is a sensitive modality for the identification of Barrett's metaplasia.

BACKGROUND: The "gold standard" and only accurate method for diagnosing Barrett's esophagus is by esophagogastroduodenoscopy with biopsy. We evaluated the ability of high-resolution endoluminal sonography (HRES) to detect the mucosal changes in Barrett's esophagus. METHODS: Seventeen patients with documented Barrett's and 12 normal controls underwent endoscopy with HRES examination using a 20 MHz ultrasound transducer to evaluate for mucosal changes. HRES examinations were videotaped then reviewed by an unblinded investigator to identify criteria possibly diagnostic of Barrett's and then by a blinded investigator to test the validity of these criteria. Barrett's was diagnosed by HRES if the second hypoechoic layer appeared thicker than the first hyperechoic layer of the mucosa. Normal mucosa was defined as having a pencil-thin second hypoechoic layer on HRES. Measurements of the second hypoechoic layer were made using a computer and compared in patients with Barrett's and patients with normal esophagus. RESULTS: All 17 patients with Barrett's were correctly identified by HRES (sensitivity 100%). Ten of 12 controls were correctly identified as normal (specificity 86%). There was good correlation between HRES and pathologic diagnoses (r 0.86). The second hypoechoic layer was significantly thicker in Barrett's patients than in normal controls (p < .001). CONCLUSIONS: HRES is a sensitive new method for identifying Barrett's esophagus. However, dysplasia could not be identified by HRES in this study.