Mistakenly picking and eating poisonous mushrooms can cause acute poisoning. In August 2020, Qingdao Hospital of Traditional Chinese Medicine handled a poisonous mushroom poisoning incident, conducted epidemiological investigation on all poisoned patients, collected suspicious food, clinical manifestations, clinical test results and treatment conditions, and identified the mushrooms as Amanita fuliginea poisoning after morphological identification. In this incident, 6 people ate grey goose paste, of which 4 were sick with a incubation period of 6~12 h. The clinical manifestations were gastrointestinal symptoms such as nausea, vomiting and diarrhea, liver and kidney damage. After symptomatic support treatment, hemoperfusion or continuous hemofiltration treatment, the patients were cured and discharged. It is suggested to strengthen the popular science education on poisonous mushroom poisoning and improve the ability of identification and clinical treatment of poisonous mushrooms in grass-roots medical institutions.
Amanita ; Hemoperfusion ; Humans ; Liver ; Mushroom Poisoning/therapy*

To eat unidentified or misidentified mushrooms taken from the wild can be very dangerous. In the vast majority of toxic mushroom ingestions in Korea, the mushroom was incorrectly identified. In general, poisoning of toxic mushrooms can be classified into seven types according to the toxins that they contain; amatoxin, gyromitrin, coprine, muscarine, ibotenic acid-muscimol, psilocybin-psilocin and gastrointestinal irritants. When clinicians care for a patient who ingested a toxic mushroom, it is very important to identify what kind of mushroom may have caused a patient's illness. But, in clinical practice, accurate botanical identification of the mushroom can be very difficult. Therefore, for estimating the caused mushroom and adequate treatment of poisoning, clinicians should know the type and treatment of toxic mushroom poisoning.
Agaricales* ; Edetic Acid ; Humans ; Irritants ; Korea* ; Muscarine ; Mushroom Poisoning* ; Poisoning

Mushroom-related poisoning can cause acute kidney injury. Here we report a case of acute kidney injury after ingestion of Amanita punctata, which is considered an edible mushroom. Gastrointestinal symptoms occurred within 24 hours from the mushroom intake and were followed by an asymptomatic period, acute kidney injury, and elevation of liver and pancreatic enzymes. Kidney function recovered with supportive care. Nephrotoxic mushroom poisoning should be considered as a cause of acute kidney injury.
Acute Kidney Injury* ; Agaricales ; Amanita* ; Eating ; Kidney ; Liver ; Mushroom Poisoning ; Poisoning*

Mushroom poisoning widely reported in Oriental and Western literature, is typically caused by accidental ingestion of toxic mushrooms that resemble edible mushrooms. Reports about poisoning due to species of Omphalotus, Amanita, Clitocybe, and other toxic mushroom species have been reported; toxicity depends on the mushroom species and the amount of toxin, which varies according to the climatic and environmental conditions. Symptoms of poisoning, such as unspecific nausea, vomiting, and diarrhea, as well as intestinal, hepatic and renal toxicities, also vary according to the mushroom species. Most patients recover with anti-muscarinic therapy and supportive care for nonspecific symptoms; however some cases of poisoning are fatal in children and elderly people. We report a case of sudden death due to mushroom poisoning in a 74-year-old woman, with hemorrhagic enteritis.
Agaricales* ; Aged ; Amanita ; Child ; Death, Sudden ; Diarrhea ; Eating ; Enteritis* ; Female ; Humans ; Mushroom Poisoning* ; Nausea ; Poisoning ; Vomiting

Adult ; Aged ; Child ; Child, Preschool ; Female ; Gastric Lavage ; Humans ; Male ; Middle Aged ; Mushroom Poisoning ; therapy

Humans ; Liver Diseases ; etiology ; therapy ; Male ; Middle Aged ; Mushroom Poisoning ; therapy ; Plasmapheresis

Mushroom and fish bile toxins are the most representative toxins of food origin. According to the clinical manifestations, renal injury caused by mushroom toxins can be divided into early-, late-, and delayed-onset. Fish bile toxins mainly cause acute renal tubular necrosis and food contamination related to renal injury includes chemical and biological contamination. Urinary calculus and renal failure caused by "poisonous milk powder" is a typical, food-related chemical contamination event. E.coli contaminated cucumber caused hemolytic uremic syndrome in 3 493 people. Contamination of the food chain is spreading from land to sea and to sky. It requires the efforts of the whole society to prevent human food chain contamination.
Animals ; Bile ; Child ; Fishes ; Food Chain ; Food Contamination ; Humans ; Kidney Diseases ; etiology ; Mushroom Poisoning ; complications

Adult ; Child ; Early Diagnosis ; Female ; Humans ; Male ; Mushroom Poisoning ; diagnosis ; therapy

OBJECTIVES: To develop a method for the simultaneous and rapid detection of five mushroom toxins (α-amanitin, phallacidin, muscimol, muscarine and psilocin) in blood by ultra-high performance liquid chromatography-high resolution mass spectrometry (UPLC-HRMS). METHODS: The blood samples were precipitated with acetonitrile-water solution(V_acetonitril∶V_water=3∶1) and PAX powder, then separated on ACQUITY Premier C₁₈ column, eluted gradient. Five kinds of mushroom toxins were monitored by FullMS-ddMS²/positive ion scanning mode, and qualitative and quantitative analysis was conducted according to the accurate mass numbers of primary and secondary fragment ions. RESULTS: All the five mushroom toxins had good linearity in their linear range, with a determination coefficient (R²)≥0.99. The detection limit was 0.2-20 ng/mL. The ration limit was 0.5-50 ng/mL. The recoveries of low, medium and high additive levels were 89.6%-101.4%, the relative standard deviation was 1.7%-6.7%, the accuracy was 90.4%-101.3%, the intra-day precision was 0.6%-9.0%, the daytime precision was 1.7%-6.3%, and the matrix effect was 42.2%-129.8%. CONCLUSIONS The method is simple, rapid, high recovery rate, and could be used for rapid and accurate qualitative screening and quantitative analysis of various mushroom toxins in biological samples at the same time, so as to provide basis for the identification of mushroom poisoning events.
Agaricales ; Chromatography, High Pressure Liquid ; Humans ; Mushroom Poisoning/diagnosis* ; Tandem Mass Spectrometry/methods*

Objective: To explore the characteristics of Banna miniature pig liver failure induced by amanita exitialis. Methods: From September to October 2020, a reverse high performance liquid chromatography (RP-HPLC) method was used to determine the toxin content of amanita exitialis solution, and 2.0 mg/kg amanita exitialis solution (α-amanitins+β-amanitins) was administered orally to Banna miniature pigs. Toxic symptoms, blood biochemical indexes and histopathological changes of liver, heart and kidney were observed at each time point. Results: All Banna miniature pigs died within 76 h of exposure, and different degrees of digestive tract symptoms such as nausea, vomiting and diarrhea appeared between 6 and 36 h. The biochemical indexes of alanine aminotransferase, aspartate aminotransferase, total bilirubin, lactate dehydrogenase, myoglobin, creatine kinase isoenzyme, blood urea nitrogen and creatinine increased significantly at 52 h after exposure, and the differences were statistically significant compared with 0 h (P<0.05). The bleeding of liver and heart was obvious under macroscopic and microscopic observation, hepatocyte necrosis, renal tubule epithelial cell swelling. Conclusion: Large dose of amanita exitialis can cause acute liver failure of Banna miniature pigs, which is in line with the pathophysiological characteristics of acute liver failure, and lays a foundation for further research on the toxic mechanism and detoxification drugs of amanita exitialis induced liver failure.
Animals ; Swine ; Amanitins/metabolism* ; Swine, Miniature/metabolism* ; Amanita/metabolism* ; Liver Failure, Acute ; Mushroom Poisoning/diagnosis*