Myoglobinuria and sea-snake-bite poisoning

Medically important snakes and snakebite envenoming in Iran

Snakebite is a common health condition in Iran with a diverse snake fauna, especially in tropical southern and mountainous western areas of the country with plethora of snake species. The list of medically important snakes, circumstances and effects of their bite, and necessary medical care require critical appraisal and should be updated regularly. This study aims to review and map the distributions of medically important snake species of Iran, re-evaluate their taxonomy, review their venomics, describe the clinical effects of envenoming, and discuss medical management and treatment, including the use of antivenom. Nearly 350 published articles and 26 textbooks with information on venomous and mildly venomous snake species and snakebites of Iran, were reviewed, many in Persian (Farsi) language, making them relatively inaccessible to an international readership. This has resulted in a revised updated list of Iran's medically important snake species, with taxonomic revisions of some, compilation of their morphological features, remapping of their geographical distributions, and description of species-specific clinical effects of envenoming. Moreover, the antivenom manufactured in Iran is discussed, together with treatment protocols that have been developed for the hospital management of envenomed patients.

Australian Sea Snake Envenoming Causes Myotoxicity and Non-Specific Systemic Symptoms - Australian Snakebite Project (ASP-24)

Background: Sea snakes are venomous snakes found in the warm parts of the Indo-Pacific, including around Australia. Most sea snake envenoming causes myotoxicity, but previous Australian case reports describe neurotoxicity. We aimed to describe the epidemiology and clinical presentation of Australian sea snake envenoming and the effectiveness of antivenom.

Methods: Patients were recruited to the Australian Snakebite Project (ASP), an Australia-wide prospective observational study recruiting all patients with suspected or confirmed snakebite >2 years. Information about demographics, bite circumstances, species involved, clinical and laboratory features of envenoming, and treatment is collected and entered into a purpose-built database.

Results: Between January 2002 and August 2020, 13 patients with suspected sea snake bite were recruited to ASP, 11 were male; median age was 30 years. Bites occurred in Queensland and Western Australia. All patients were in or around, coastal waters at the time of bite. The species involved was identified in two cases (both Hydrophis zweifeli). Local effects occurred in 9 patients: pain (5), swelling (5), bleeding (2), bruising (1). Envenoming occurred in eight patients and was characterised by non-specific systemic features (6) and myotoxicity (2). Myotoxicity was severe (peak CK 28200 and 48100 U/L) and rapid in onset (time to peak CK 13.5 and 15.1 h) in these two patients. Non-specific systemic features included nausea (6), headache (6), abdominal pain (3), and diaphoresis (2). Leukocytosis, neutrophilia, and lymphopenia occurred in both patients with myotoxicity and was evident on the first blood test. No patients developed neurotoxicity or coagulopathy. Early Seqirus antivenom therapy was associated with a lower peak creatine kinase.

Conclusion: While relatively rare, sea snake envenoming is associated with significant morbidity and risk of mortality. Early antivenom appears to have a role in preventing severe myotoxicity and should be a goal of therapy.

An unusual case of gross myoglobinuria in a child following Russell's viper (Daboia russelii) envenomation

Overt myoglobinuria associated with myotoxicity is a classic feature of sea snake envenomation. Russell's viper bites usually result in coagulopathy, neurotoxicity and nephrotoxicity but rarely myotoxicity has been reported, especially in the Sri Lankan variety (Daboia russelii). All those studies have demonstrated mild degree myotoxicity with microscopic level myoglobinuria. We report what is probably the first case of gross myoglobinuria in a child following a Russell's viper bite with biochemical evidence of significant myotoxicity well beyond the levels that have been previously reported.

Spine-bellied sea snake (Hydrophis curtus) venom shows greater skeletal myotoxicity compared with cardiac myotoxicity

For the first time the impedance-based xCELLigence real-time cell analysis system was used to measure the myotoxicity of sea snake venom. With a focus on the spine-bellied sea snake (Hydrophis curtus), the venom of four sea snake species and three terrestrial snake species were compared for myotoxicity against a human skeletal muscle cell line (HSkMC). Hydrophis curtus venom was also tested on a human cardiac muscle cell line (HCM). Surprisingly, all four sea snake venoms tested on HSkMC produced an initial 100-280% rise in xCELLigence cell index that peaked within the first two hours before falling. The cell index rise of H. curtus venom was correlated with the WST-1 cell proliferation assay, which demonstrated an increase in mitochondrial metabolism. The myotoxicity of H. curtus was 4.7-8.2 fold less potent than the other sea snakes tested, the Australian beaked sea snake (Hydrophis zweifeli), the elegant sea snake (Hydrophis elegans) and the olive sea snake (Aipysurus laevis). If our cell-based results translate to H. curtus envenomations, this implies that H. curtus would be less myotoxic than the other three. Yet the myotoxicity of H. curtus venom to cardiac muscle cells was nine times weaker than for skeletal muscle cells, providing evidence that the venom has a selective effect on skeletal muscle cells. This evidence, combined with the slow-acting nature of the venom, supports a digestive role for sea snake myotoxins.

The Venom of the Spine-Bellied Sea Snake (Hydrophis curtus): Proteome, Toxin Diversity and Intraspecific Variation

The spine-bellied sea snake (Hydrophis curtus) is known to cause human deaths, yet its venom composition has not yet been proteomically characterised. An in-depth proteomic analysis was performed on H. curtus venom from two different seasons, January and June, corresponding to adults and subadults, respectively. Venoms from adult and subadult H. curtus individuals were compared using reversed-phase high-performance liquid chromatography (RP-HPLC), matrix-assisted laser desorption ionisation-time of flight (MALDI-TOF) mass spectrometry and liquid chromatography electrospray ionisation mass spectrometry (LC-ESI-MS) to detect intraspecific variation, and the molecular weight data obtained with ESI-MS were used to assess toxin diversity. RP-HPLC and LC-ESI-MS/MS were used to characterise the venom proteome and estimate the relative abundances of protein families present. The most abundant protein family in January and June venoms is phospholipase A₂ (PLA₂: January 66.7%; June 54.5%), followed by three-finger toxins (3FTx: January 30.4%; June 40.4%) and a minor component of cysteine-rich secretory proteins (CRISP: January 2.5%; June 5%). Trace amounts of snake venom metalloproteinases (SVMP), C-type lectins and housekeeping and regulatory proteins were also found. Although the complexity of the venom is low by number of families present, each family contained a more diverse set of isoforms than previously reported, a finding that may have implications for the development of next-generation sea snake antivenoms. Intraspecific variability was shown to be minor with one obvious exception of a 14,157-Da protein that was present in some January (adult) venoms, but not at all in June (subadult) venoms. There is also a greater abundance of short-chain neurotoxins in June (subadult) venom compared with January (adult) venom. These differences potentially indicate the presence of seasonal, ontogenetic or sexual variation in H. curtus venom.

Clinical and Pharmacological Investigation of Myotoxicity in Sri Lankan Russell's Viper (Daboia russelii) Envenoming

BACKGROUND

Sri Lankan Russell's viper (Daboia russelii) envenoming is reported to cause myotoxicity and neurotoxicity, which are different to the effects of envenoming by most other populations of Russell's vipers. This study aimed to investigate evidence of myotoxicity in Russell's viper envenoming, response to antivenom and the toxins responsible for myotoxicity.

METHODOLOGY AND FINDINGS

Clinical features of myotoxicity were assessed in authenticated Russell's viper bite patients admitted to a Sri Lankan teaching hospital. Toxins were isolated using high-performance liquid chromatography. In-vitro myotoxicity of the venom and toxins was investigated in chick biventer nerve-muscle preparations. Of 245 enrolled patients, 177 (72.2%) had local myalgia and 173 (70.6%) had local muscle tenderness. Generalized myalgia and muscle tenderness were present in 35 (14.2%) and 29 (11.8%) patients, respectively. Thirty-seven patients had high (>300 U/l) serum creatine kinase (CK) concentrations in samples 24h post-bite (median: 666 U/l; maximum: 1066 U/l). Peak venom and 24h CK concentrations were not associated (Spearman's correlation; p = 0.48). The 24h CK concentrations differed in patients without myotoxicity (median 58 U/l), compared to those with local (137 U/l) and generalised signs/symptoms of myotoxicity (107 U/l; p = 0.049). Venom caused concentration-dependent inhibition of direct twitches in the chick biventer cervicis nerve-muscle preparation, without completely abolishing direct twitches after 3 h even at 80 μg/ml. Indian polyvalent antivenom did not prevent in-vitro myotoxicity at recommended concentrations. Two phospholipase A2 toxins with molecular weights of 13kDa, U1-viperitoxin-Dr1a (19.2% of venom) and U1-viperitoxin-Dr1b (22.7% of venom), concentration dependently inhibited direct twitches in the chick biventer cervicis nerve-muscle preparation. At 3 μM, U1-viperitoxin-Dr1a abolished twitches, while U1-viperitoxin-Dr1b caused 70% inhibition of twitch force after 3h. Removal of both toxins from whole venom resulted in no in-vitro myotoxicity.

CONCLUSION

The study shows that myotoxicity in Sri Lankan Russell's viper envenoming is mild and non-life threatening, and due to two PLA2 toxins with weak myotoxic properties.

Early demographic and clinical predictors of developing acute kidney injury in snake bite patients: A retrospective controlled study from an Indian tertiary care hospital in North Eastern Uttar Pradesh India

Aims:

This study was conducted retrospectively to define early demographic and clinical predictors for acute kidney injury (AKI) among snake bite patients at the time of hospital admission.

Materials and Methods:

We analyzed 138 cases with a poisonous snake bite. Patients were classified into two groups according to the presence and absence of AKI. The data regarding clinical features and demographic profile of these patients were collected from the hospital records in a prestructured pro forma and statistically compared.

Results:

Of the 138 patients of venomous snake bite, 62 developed AKI (44.92%). Patients who developed AKI were older in age. Moreover, prolonged bite to anti-snake venom (ASV) time had a significant relationship in developing AKI (P < 0.05). Among the clinical features, there was an independent positive association of AKI with abdomen pain, tenderness and vomiting, cellulitis, bleeding tendencies, myalgia, and black or brown urine (P < 0.05). Neurological features were inversely associated with renal involvement.

Conclusion:

We found that marked abdominal pain, tenderness and vomiting, myalgia, black or brown urine, bite site cellulitis, bleeding tendencies, and prolonged (>2 h) bite to ASV time were significantly associated with the development of AKI in snake bite patients.

Danger in the reef: Proteome, toxicity, and neutralization of the venom of the olive sea snake, Aipysurus laevis

Four specimens of the olive sea snake, Aipysurus laevis, were collected off the coast of Western Australia, and the venom proteome was characterized and quantitatively estimated by RP-HPLC, SDS-PAGE, and MALDI-TOF-TOF analyses. A. laevis venom is remarkably simple and consists of phospholipases A2 (71.2%), three-finger toxins (3FTx; 25.3%), cysteine-rich secretory proteins (CRISP; 2.5%), and traces of a complement control module protein (CCM; 0.2%). Using a Toxicity Score, the most lethal components were determined to be short neurotoxins. Whole venom had an intravenous LD50 of 0.07 mg/kg in mice and showed a high phospholipase A2 activity, but no proteinase activity in vitro. Preclinical assessment of neutralization and ELISA immunoprofiling showed that BioCSL Sea Snake Antivenom was effective in cross-neutralizing A. laevis venom with an ED50 of 821 μg venom per mL antivenom, with a binding preference towards short neurotoxins, due to the high degree of conservation between short neurotoxins from A. laevis and Enhydrina schistosa venom. Our results point towards the possibility of developing recombinant antibodies or synthetic inhibitors against A. laevis venom due to its simplicity.

Venomics of the beaked sea snake, Hydrophis schistosus: A minimalist toxin arsenal and its cross-neutralization by heterologous antivenoms

The venom proteome of Hydrophis schistosus (syn: Enhydrina schistosa) captured in Malaysian waters was investigated using reverse-phase HPLC, SDS-PAGE and high-resolution liquid chromatography-tandem mass spectrometry. The findings revealed a minimalist profile with only 18 venom proteins. These proteins belong to 5 toxin families: three-finger toxin (3FTx), phospholipase A2 (PLA2), cysteine-rich secretory protein (CRISP), snake venom metalloprotease (SVMP) and L-amino acid oxidase (LAAO). The 3FTxs (3 short neurotoxins and 4 long neurotoxins) constitute 70.5% of total venom protein, 55.8% being short neurotoxins and 14.7% long neurotoxins. The PLA2 family consists of four basic (21.4%) and three acidic (6.1%) isoforms. The minor proteins include one CRISP (1.3%), two SVMPs (0.5%) and one LAAO (0.2%). This is the first report of the presence of long neurotoxins, CRISP and LAAO in H. schistosus venom. The neurotoxins and the basic PLA2 are highly lethal in mice with an intravenous median lethal dose of <0.2 μg/g. Cross-neutralization by heterologous elapid antivenoms (Naja kaouthia monovalent antivenom and Neuro polyvalent antivenom) was moderate against the long neurotoxin and basic PLA2, but weak against the short neurotoxin, indicating that the latter is the limiting factor to be overcome for improving the antivenom cross-neutralization efficacy.

Secreted phospholipases A2 of snake venoms: effects on the peripheral neuromuscular system with comments on the role of phospholipases A2 in disorders of the CNS and their uses in industry

Neuro- and myotoxicological signs and symptoms are significant clinical features of envenoming snakebites in many parts of the world. The toxins primarily responsible for the neuro and myotoxicity fall into one of two categories--those that bind to and block the post-synaptic acetylcholine receptors (AChR) at the neuromuscular junction and neurotoxic phospholipases A2 (PLAs) that bind to and hydrolyse membrane phospholipids of the motor nerve terminal (and, in most cases, the plasma membrane of skeletal muscle) to cause degeneration of the nerve terminal and skeletal muscle. This review provides an introduction to the biochemical properties of secreted sPLA2s in the venoms of many dangerous snakes and a detailed discussion of their role in the initiation of the neurologically important consequences of snakebite. The rationale behind the experimental studies on the pharmacology and toxicology of the venoms and isolated PLAs in the venoms is discussed, with particular reference to the way these studies allow one to understand the biological basis of the clinical syndrome. The review also introduces the involvement of PLAs in inflammatory and degenerative disorders of the central nervous system (CNS) and their commercial use in the food industry. It concludes with an introduction to the problems associated with the use of antivenoms in the treatment of neuro-myotoxic snakebite and the search for alternative treatments.

Snakebite envenoming from a global perspective: Towards an integrated approach

Snakebite envenoming is a neglected public health challenge of compelling importance in many regions of the world, particularly sub-Saharan Africa, Asia, Latin America and Papua-New Guinea. Addressing the problem of snakebite effectively demands an integrated multifocal approach, targeting complex problems and involving many participants. It must comprise: (a) Acquisition of reliable information on the incidence and mortality attributable to snakebite envenoming, and the number of people left with permanent sequelae. (b) Improvements in production of effective and safe antivenoms, through strategies aimed at strengthening the technological capacity of antivenom manufacturing laboratories. (c) Increasing the capacity of low-income countries to produce specific immunogens(snake venoms) locally, and to perform their own quality control of antivenoms. (d) Commitments from regional producers to manufacture antivenoms for countries where antivenom production is not currently feasible. (e) Implementation of financial initiatives guaranteeing the acquisition of adequate volumes of antivenom at affordable prices in low-income countries. (f) Performance of collaborative studies on the safety and effectiveness of antivenoms assessed preclinically and by properly designed clinical trials. (g) Development of antivenom distribution programmes tailored to the real needs and epidemiological situations of rural areas in each country. (h) Permanent training programmes for health staff, particularly in rural areas where snakebites are frequent.(i) Implementation of programmes to support those people whose snakebites resulted in chronic disabilities. (j) Preventive and educational programmes at the community level, with the active involvement of local organizations and employing modern methods of health promotion. Such an integrated approach, currently being fostered by the Global Snake Bite Initiative of the International Society on Toxinology and by the World Health Organization, will help to alleviate the enormous burden of human suffering inflicted by snakebite envenoming.

Snakebite-induced acute kidney injury: data from Southeast Anatolia

Renal failure is an important complication of snakebite and a major cause of mortality. We aimed to study the clinical profile of snake envenomation in Southeast Anatolia, Turkey, in an adult population. We retrospectively analyzed the records of 200 snakebite victims from 1998 to 2006 at the Dicle University School of Medicine, Diyarbakir, Turkey. Sixteen patients (8%) developed AKI (acute kidney injury). Of those, 25% required dialysis and 18% died. There was no difference between groups in age, arrival time to hospital, and hospital stay time. Both groups received similar hydration and therapy at admission. Disseminated intravascular coagulation (DIC) was observed in 25% of the AKI group and was significantly higher than the non-AKI group (7.1%; p = 0.014). There was no significant difference regarding hemoglobin, platelet levels, and prothrombin time at admission. The prevalence of thrombocytopenia (<150,000 K/UL ) was 60% in the AKI group and 40% in the non-AKI group (p > 0.05). WBC count was significantly higher in the AKI group than in those without AKI (p = 0.001); serum albumin was significantly lower in the AKI group than in those without AKI (p = 0.013). AKI is an important complication of snakebite that may lead to mortality. Despite some troublesome aspects due to its retrospective design, this is a large series from Southeast Anatolia of Turkey in an adult population. Subjects with high WBC, low albumin, and DIC should be closely followed up for the development of AKI.

Snakebite-induced acute renal failure. A case report and review of the literature

Snakebite is not an uncommon cause of acute renal failure (ARF) in developing countries. We report a12-year-old boy who presented with oliguric ARF following snakebite. He had pallor, icterus, generalized edema, hypertension, and was oliguric. Investigations revealed severe azotemia, microangiopathic hemolytic anemia, thrombocytopenia, prolonged coagulation parameters, and raised fibrin degradation products, suggesting disseminated intravascular coagulation as the cause of ARF. The patient improved with antisnake venom, dialysis, and other supportive treatment.

Absence of myocardial involvement in children victims of Crotalus durissus terrificus envenoming

The myotoxic activity of the venom of Crotalus durissus terrificus is demonstrable by increased serum levels of the enzymes creatine kinase (CK), lactate dehydrogenase (LD), and aspartate aminotransferase. Serial measurements of CK, LD and their isoenzymes in bite victims showed a pattern similar to that observed in acute myocardial infarction, although the clinical course and electro- and echocardiographic data did not suggest cardiac involvement. These data have raised the hypothesis that crotalid venom preferentially causes damage to type I and/or type IIa fibers, which contain quantities of CK-MB and LD1 similar to those found in cardiac fibers. In order to detect a possible concomitant silent cardiac involvement, seven children with severe crotalid envenoming were studied. Serum troponin I, determined more than once in each patient, were found to be normal. These data demonstrate the absence of cardiac involvement in these patients envenomed by C. durissus terrificus and confirmed the skeletal muscle origin of the elevated CK-MB.

Sea snake Hydrophis cyanocinctus venom. II. Histopathological changes, induced by a myotoxic phospholipase A2 (PLA2-H1)

A toxic phospholipase A2 (PLA2-H1), isolated from the venom of the sea snake Hydrophis cyanocinctus, was tested for its ability to induce myonecrosis and histopathological changes in albino rats and mice. Induction of myonecrosis was demonstrated by their ability to release creatine kinase (CK) from damaged muscle fibers and direct histopathological examination of the injected muscles (i.m.). PLA2-H1 exhibits intense myonecrosis characterized by the changes including, necrosis and edematous appearance with cellular infiltrate, vacuolation and degenerated muscle cells with delta lesions and heavy edema in between the cells. No myoglobinuria was noted in any group of animals. The purified PLA2-H1 was also administered intraperitoneally into the experimental animals and tissue samples were taken at several time intervals. Light microscopic examination of the kidney sections revealed severe damage, evident by focal tubular necrosis, complete disquamation of epithelial lining and epithelial degeneration of tubules in all test animals. Light micrographs of liver sections after 24 h of injection shows fatty infiltration in parenchyma and squashed hepatocytes, while after 48 h, fatty vacuolation of parenchyma in a generalized pattern was observed. Furthermore, sections of the lungs of the same group of animals (48 h) show dilated bronchia and marked infiltration of inflammatory cells within alveoli. Our results suggest that the purified PLA2-H1 induced moderate myotoxicity in muscles and mild histopathological changes in other vital organs without myoglobinuria.

Successful myoblast transplantation in primates depends on appropriate cell delivery and induction of regeneration in the host muscle

Myoblast transplantation (MT) may be a potential treatment for severe recessive hereditary myopathies. The limited results of MT in clinical trials led us to improve this technique in monkeys, an animal model phylogenetically similar to humans. Three Macaca mulata monkeys were used as donors and six as receivers for MT. Myoblasts were grown in culture from muscle biopsies of adult monkeys and infected with a retroviral vector encoding the LacZ gene. Different numbers of cells (i.e., 4 x 10(6), 8 x 10(6), and 24 x 10(6) cells) were transplanted into different muscles and 8 x 10(6) cells (resuspended in a notexin solution) were injected in one muscle of four monkeys. For these transplantations, the cell suspension (in a volume of about 100 microl) was injected at 35 sites less than 1 mm apart. Two other monkeys received 100 x 10(6) myoblasts resuspended in 1 ml of HBSS or 1 ml of notexin. For these two monkeys, the myoblasts were injected at 200-250 sites within a small portion of the muscle. All monkeys were immunosuppressed with daily injections of FK506. Four weeks after MT, the transplanted muscle portions were biopsied and the presence of beta-galactosidase-positive (beta-Gal+) muscle fibers was investigated. The number of beta-Gal+ fibers was 822 +/- 150 (site grafted with 4 x 10(6) cells), 1253 +/- 515 (8 x 10(6) cells), 1084 +/- 278 (24 x 10(6)), and 2852 +/- 1211 (notexin). In the monkeys grafted with 100 x 10(6) myoblasts, the number of beta-Gal+ fibers was 4850 (site without notexin) and 9600 (site with notexin). We demonstrated that a precise mechanical distribution of myoblasts into the tissue improves substantially MT in primates. The presence of notexin with the transplanted cells further increased the success of their transplantation. These are the best results obtained either with MT or gene therapy in primates and they encourage the possibility to human MT trials.

A case of intestinal infarction following Vipera aspis bite

A case of Vipera aspis bite followed by severe envenomation, shock, neurotoxic symptoms, myoglobinuria and coagulation disorders with thrombosis of the iliac vessels and intestinal infarction is described. A right hemicolectomy had to be performed. Treatment is described in detail. European adder bites may cause, although uncommonly, severe envenoming with unusual symptoms. The attending doctor must be prepared to face unusual diagnostic and therapeutic problems.

Hugh Alistair Reid OBE MD: investigation and treatment of snake bite

Alistair Reid was an outstanding clinician, epidemiologist and scientist. At the Penang General Hospital, Malaya, his careful observation of sea snake poisoning revealed that sea snake venoms were myotoxic in man leading to generalized rhabdomyolysis, and were not neurotoxic as observed in animals. In 1961, Reid founded and became the first Honorary Director of the Penang Institute of Snake and Venom Research. Effective treatment of sea snake poisoning required specific antivenom which was produced at the Commonwealth Serum Laboratories in Melbourne from Enhydrina schistosa venom supplied by the Institute. From the low frequency of envenoming following bites, Reid concluded that snakes on the defensive when biting man seldom injected much venom. He provided clinical guidelines to assess the degree of envenoming, and the correct dose of specific antivenom to be used in the treatment of snake bite in Malaya. Reid demonstrated that the non-clotting blood of patients bitten by the pit viper, Calloselasma rhodostoma [Ancistrodon rhodostoma] was due to venom-induced defibrination. From his clinical experience of these patients, Reid suggested that a defibrinating derivative of C. rhodostoma venom might have a useful role in the treatment of deep vein thrombosis. This led to Arvin (ancrod) being used clinically from 1968. After leaving Malaya in 1964, Alistair Reid joined the staff of the Liverpool School of Tropical Medicine, as Senior Lecturer. Enzyme-linked immunosorbent assay (ELISA) for detecting and quantifying snake venom and venom-antibody was developed at the Liverpool Venom Research Unit: this proved useful in the diagnosis of snake bite, in epidemiological studies of envenoming patterns, and in screening of antivenom potency. In 1977, Dr H. Alistair Reid became Head of the WHO Collaborative Centre for the Control of Antivenoms based at Liverpool.

Renal lesions in rhabdomyolysis caused by Pseudechis australis snake myotoxin

The renal lesions at various time intervals after i.m. injection of Pseudechis australis myotoxin (PA myotoxin) causing myoglobinuria in mice was studied. Biochemical assay of serum creatine phosphokinase (CK) and lactate dehydrogenase (LDH) showed marked elevations [7166 +/- 2064 IU and 1626 +/- 211 Berger-Broida U/ml (B-B U/ml)] six hours after injection, indicative of rhabdomyolysis. Serum creatinine (1.6 +/- 0.39) and urea (147 +/- 40) showed significant rise by 48 hours indicative of acute renal failure (ARF). Immunodiffusion showed the presence of myoglobin in the urine (myoglobinuria) of experimental animals. Light microscopic (LM) and scanning electron microscopic (SEM) studies of the urinary sediments from experimental mice revealed granular casts of varying size and shape. LM of kidney showed casts from one hour and tubulopathy with degenerated tubular epithelial cell from 12 hours onwards. Focal glomerular changes, such as dilated Bowman's space with poorly stained substance and reduction in number of glomerular tufts were observed. Immunofluorescence microscopy for myoglobin showed fluorescence of the casts in the tubules. Transmission electron microscopy (TEM) showed electron dense casts occupying the entire lumen of the distal convoluted tubules (DCT). The proximal convoluted tubules (PCT) showed features of proximal tubular necrosis (PTN). There was reduction in the basal infolding with activation of lysosomal system in the PCT. The glomeruli showed changes in the visceral epithelium that included intracellular edema, vesiculation and occasional fusion of the podocytes. Numerous granular materials were observed in the Bowman's space as well as in the lumen of the capillaries from 1 to 24 hours. Electron dense deposits of the glomerular basement membrane (GBM) capillaries were observed from 1 to 24 hours. SEM study revealed loss of microvilli of the PCT and some tubular lumen were filled with cast like material. Some glomeruli displayed a relatively flattened podocytes with thickened major foot processes. Regeneration of the tubules were seen from three weeks onwards.

Electrocardiographic abnormalities in patients bitten by taipans (Oxyuranus scutellatus canni) and other elapid snakes in Papua New Guinea

Envenoming by a number of species of snake may affect the myocardium or cause electrocardiographic changes; several different mechanisms have been proposed. In a prospective study of snake bite in Papua New Guinea, electrocardiographic changes were observed in 36 of 69 patients (52%) envenomed by the taipan (Oxyuranus scutellatus), 2 of 6 (33%) envenomed by death adders (Acanthophis sp.) and one envenomed by the brown snake (Pseudonaja textilis). Septal T wave inversion and bradycardias, including atrioventricular block, were the commonest abnormalities. There was no haemodynamic deterioration. The cause of these changes is uncertain; only 2 of 24 patients (8.3%) with electrocardiographic changes had markedly elevated plasma concentrations of cardiac troponin T, a sensitive and specific marker of myocardial damage. This suggests that myocardial damage is uncommon following bites by these species. Electrocardiographic abnormalities are most likely to have been caused by a direct toxic effect of a venom component upon cardiac myocyte function; in taipan bites, taicatoxin, a calcium channel blocker, might be responsible.

Notexin-induced muscle injury in the dog

Notexin, a myotoxic phospholipase, was used to induce focal necrosis in the sartorius muscles of normal mixed-breed adult dogs and in 12-week-old beagles. Notexin injury caused pathologic changes similar to those of Duchenne muscular dystrophy (DMD) and its canine homologue, golden retriever muscular dystrophy (GRMD). All three conditions are characterized by increased serum creatine kinase (CK) levels, sarcolemmal defects, delta lesions, hyaline degeneration of myofibers, calcium-positive myofibers, and minimal effects on neurovascular structures. Four and 24 h after exposure to notexin, serum CK levels were elevated, and many myofibers were necrotic. In addition, by 24 h the necrotic areas were heavily invaded by mononuclear cells, and calcium-positive myofibers were prominent. Capillaries appeared intact even in areas of marked myonecrosis. Massive cellular infiltrate and myotube formation was evident at 3 days post injury. By 7 days, most affected fascicles were occupied by small immature myofibers. Regeneration was largely complete at 21 days. Our results suggest that notexin-induced muscle injury in dogs will be useful in the evaluation of potential therapies for DMD such as myoblast transplantation.

Pathologic changes induced by phospholipase A2 isolated from the venom of Collett's snake, Pseudechis colletti: a light and electron microscopic study

Pseudechis colletti is an Australian elapid snake with a range limited to central Queensland, Australia. The venom of this snake, as well as that of several other Australian elapids, has been shown to contain a phospholipase A2 (PLA2) which can cause a marked myoglobinuria in mice. Few studies have described the histopathologic and ultrastructural changes that result from myotoxic PLA2-induced damage. Our investigation demonstrated that the isolated PLA2 induced myodegeneration and necrosis in myocardium in a dose-related manner, with subsequent myoglobinuria and myoglobinuric nephropathy.

A comparative study of the biological properties of some sea snake venoms

1. The protease, phosphodiesterase, alkaline phosphomonoesterase, L-amino acid oxidase, acetylcholinesterase, phospholipase A, 5'-nucleotidase, hyaluronidase, arginine ester hydrolase, procoagulant, anticoagulant and hemorrhagic activities of ten samples of venoms from seven taxa of sea snakes were examined. 2. The results show that venoms of sea snakes of both subfamilies of Hydrophiinae and Laticaudinae are characterized by a very low level of enzymatic activities, except phospholipase A activity and, for some species, hyaluronidase activity. 3. Because of the low levels of enzymatic activities and the total lack of procoagulant and hemorrhagic activities, venom biological properties are not useful for the differentiation of species of sea snakes. Nevertheless, the unusually low levels of enzymatic activities of sea snake venoms may be used to distinguish sea snake venoms from other elapid or viperid venoms.

Acute myocardial infarction-like enzyme profile in human victims of Crotalus durissus terrificus envenoming

The clinical signs and symptoms of Crotalus durissus terrificus envenoming are due to the neurotoxic, myotoxic systemic and thrombin-like coagulating effects of the venom. The rhabdomyolysis observed after envenoming caused by snakes, the venom of which has a systemic myotoxic activity, has been limited thus far to skeletal muscle, with no reports of myocardial damage. In the present paper we report serial measurements of serum creatine kinase (CK), lactic dehydrogenase (LD) and of CK-MB and LD1 isoenzymes in human victims of Crotalus bites. The results were similar to those reported for acute myocardial infarction even though the clinical evolution, electrocardiogram and echocardiogram findings did not show any involvement of cardiac muscle. The enzymatic profile detected, as well as the pattern of focal involvement observed in muscle biopsies obtained from these patients, suggest that there may be a type of skeletal muscle fibre that is preferentially damaged by C. durissus terrificus venom, i.e., type I and/or IIa fibres, the composition of which is richer in CK-MB and LD1, and is similar to that of cardiac fibres.

Muscle necrosis caused by snake venoms and toxins

Snake bite is often associated with localised soft tissue necrosis. Less frequently victims may suffer extensive muscle damage leading to rhabdomyolysis and the loss of muscle-specific protein. This review describes the organisation and structure of mammalian skeletal muscle, and its response to myotoxic venoms and to isolated pure myotoxic venom fractions. The clinical reports of muscle damage in man following snake bite are discussed, and the various classes of myotoxic toxins are introduced. Muscle damage caused by the toxins is next described, particular emphasis being placed on the correlation between muscle pathology seen at the light level and the morphological changes seen at the level of the electron microscope. Where known, those subcellular components of the muscle fibre that are especially sensitive to assault, and those components that appear to be spared, are identified. The relevance of the selective sparing of some components to the regenerative capacity of the skeletal muscle is considered.

Snake venoms in science and clinical medicine. 3. Neuropharmacological aspects of the activity of snake venoms

Neuromuscular weakness is a common feature of snake bite. The toxins responsible for weakness either block neuromuscular transmission or they are myotoxic and damage skeletal muscle. In this article the major classes of toxins responsible for causing neuromuscular weakness are described. It is shown how a detailed knowledge of the biochemical and pharmacological properties of the toxins is essential if the clinical problems associated with bites by many species are to be properly understood. It is also shown that such an understanding allows apparent discrepancies between 'laboratory' and 'clinical' findings to be resolved.

Snake-bite-induced acute renal failure in India

Acute renal failure complicates the course in 5% to 30% of victims of severe viper poisoning. No consensus exists on the single mechanism causing acute renal failure after viper bite. It is known, however, that viper venom induces several clinical abnormalities that favor the development of acute renal failure. These alterations include a varying degree of bleeding, hypotension, circulatory collapse, intravascular hemolysis, and disseminated intravascular coagulation with or without microangiopathy. A direct cytotoxic action of snake venom on the kidney is suspected, but convincing evidence is still lacking. Severe hypocomplementemia is consistently present, but I doubt its role in the causation of renal lesions. Hypersensitivity to venomous or antivenomous protein occasionally causes acute renal failure. In sea snake poisoning, myonecrosis and myoglobinuria appear to play the predominant pathogenetic role. The renal lesions of clinical significance in envenomed patients are acute tubular and patchy or diffuse cortical necrosis. Glomerulonephritis, interstitial nephritis, and papillary necrosis have been reported in rare patients. I trust that this overview of the clinical and basic-science aspects of snake-bite-induced acute renal failure will prompt investigators to further define the pathogenetic mechanisms involved. Lessons learned may aid patients with acute renal failure of diverse causes, both here in India and around the world.

Clinical and laboratory features of South American rattlesnake (Crotalus durissus terrificus) envenomation in children

The venom of the South American rattlesnake Crotalus durissus terrificus was first reported to have mainly haemolytic and neurotoxic physiopathological activities. Later studies demonstrated the systemic myotoxic action of the venom, characterized by the release of myoglobin from damaged skeletal muscle into serum and urine, and a recent report ruled out the presence of intravascular haemolysis in 3 patients, one child and 2 adults. The present paper describes the clinical-laboratory evolution of 10 children bitten by C. durissus terrificus; 2 developed acute renal failure and one died. The myotoxic activity of the venom was evaluated by measuring serum lactic dehydrogenase, creatine kinase and aspartate aminotransferase, by detection of myoglobin in serum and urine, and by muscle biopsy. Haemolytic activity was evaluated by serial measurements of serum haemoglobin and haptoglobin and by detection of urine haemoglobin. We conclude that the signs and symptoms exhibited by patients bitten by C. durissus terrificus are due only to the myotoxic and neurotoxic action of the venom. The only patients with major morbidity were those who initially received subcutaneous antivenin and did not receive definitive antivenin therapy until later.

Exogenous ATP antagonizes the actions of phospholipase A2, local anesthetics, Ca2+ ionophore A23187, and lithium on glucose-1,6-bisphosphate levels and the activities of phosphofructokinase and phosphoglucomutase in rat muscle

ATP, added externally to the incubation medium of rat diaphragm muscles, abolished the decrease in the levels of glucose-1,6-bisphosphate (Glc-1,6-P2), the powerful regulator of carbohydrate metabolism, induced by phospholipase A2, local anesthetics, Ca2+ ionophore A23187, or lithium. Concomitantly to the changes in Glc-1,6-P2, the potent activator of phosphofructokinase (the rate-limiting enzyme in glycolysis) and phosphoglucomutase, the activities of these enzymes were reduced by the myotoxic agents and restored by exogenous ATP, when assayed under conditions in which these enzymes are sensitive to regulation by Glc-1,6-P2. These findings suggest that ATP may have broad therapeutic action, as it may stimulate the impaired glycolysis in muscle induced by various drugs and conditions which cause muscle weakness or damage.

Biotoxicology of sea snake venoms

Sea snakes are the most abundant venomous reptiles, found throughout the Indian and Pacific Oceans. Divided into two subfamilies, Laticaudinae and Hydrophiinae, all sea snakes are poisonous. Venoms are highly toxic, as indicated by low LD50 values in test animals. Toxic compounds include presynaptic and postsynaptic neurotoxins. Similarities in phylogeny are reflected in immunodiffusion patterns, immunoelectrophoresis, cross-neutralization by antivenin against heterologous venoms, and amino acid composition. The clinical syndrome following a bite is largely neurotoxic and myotoxic, with rare hepatotoxicity and nephrotoxicity. Proper emergency field therapy and timely administration of antivenin can be lifesaving. Hemodialysis may be useful when antivenin is not available.

[Rhabdomyolysis secondary to a crotalid bite (Crotalus durissus terrificus)]

Relatam-se dois casos de rabdomiólise secundária a envenenamento produzido por Crotalus durissus terrificus. O diagnóstico da rabdomiólise baseou-se na mialgia intensa e generalizada apresentada pelos pacientes e na constatação de níveis séricos elevados de CPK, TGO e DHL. A confirmação do diagnóstico foi obtida no caso n.° 2 pela detecção de mioglobina no soro através de imunoeletroforese contra soro antimioglobina humana e por biópsia muscular. Esse paciente desenvolveu também, como complicação do envenenamento ofídico, quadro clínico e laboratorial de insuficiência renal aguda. Essa complicação foi atribuída à ação nefrotóxica e hemolítica do veneno crotálico e à hipotensão arterial apresentada pelo paciente, não se afastando a possibilidade de que a rabdomiólise tenha sido um fator contribuinte para a sua instalação. Foram constatadas hipocalcemla, hiperuricemia e hiperfosfatemia grave na fase oligúria da insuficiência renal aguda, alterações peculiares quando essa condição está associada à rabdomiólise.

Myonecrosis, myoglobinuria and acute renal failure induced by South American rattlesnake (Crotalus durissus terrificus) envenomation in Brazil

The venom of the Brazilian rattlesnake Crotalus durissus terrificus is know to have hemolytic and neurotoxic physiopathological activities which may cause acute renal failure with hemoglobinuria and/or methemoglobinuria. As far as we know, no report has been published on the ability of the venom of this rattlesnake species to cause rhabdomyolysis. In the present paper we demonstrate that the venom of Brazilian snakes of the genus Crotalus can induce systemic myonecrosis. Clinical, laboratory and anatomo-pathological data for two patients referred to the University Hospital of the Faculty of Medicine of Ribeirão Preto, University of São Paulo, 24 hr after a rattlesnake bite, are presented. In both cases, exaggerated elevation of serum levels of the enzymes creatine phosphokinase, lactate dehydrogenase and glutamic-oxaloacetic transaminase were detected, as well as data suggesting acute hypercatabolic renal failure. Immunoelectrophoresis of the serum and urine of these patients, carried out against specific anti-myoglobin serum (Behringwerke), demonstrated myoglobinemia and myoglobinuria, confirming injury to muscle tissue. Electron microscopy of a calf muscle biopsy taken from the leg contralateral to the bite from one patient revealed foci of myonecrosis.