Ethylene glycol poisoning: experiences from an epidemic in Sweden.

In 1987 two lethal adult cases of accidental ethylene glycol poisoning were given spectacular attention in the Swedish mass media. This resulted in an epidemic of intentional ethylene glycol poisonings. In addition to six cases related to alcohol abuse, another 30 severe suicidal poisonings were reported to the Swedish Poison Information Centre in five months. The clinical course and outcome in these 36 severe cases are reviewed. The primary clinical manifestations were metabolic acidosis, CNS disturbances and kidney damage with circulatory failure in the most severe cases. Mortality was 17%. Fragmentation of the normal striation in heart cells was found in two of the fatal cases and severe brain damage in all fatal poisonings. The degree of acidosis but not the serum ethylene glycol level correlated with both kidney damage and outcome. Treatment included ethanol, correction of the metabolic acidosis and dialysis. Four patients with serum ethylene glycol concentrations of 10-20 mmol/L (620-1240 mg/L) but with no or minimal metabolic acidosis were treated with ethanol alone; none of these patients developed renal damage.     

Current management of ethylene glycol poisoning.

Ethylene glycol, a common antifreeze, coolant and industrial solvent, is responsible for many instances of accidental and intentional poisoning annually. Following ingestion, ethylene glycol is first hepatically metabolised to glycoaldehyde by alcohol dehydrogenase. Glycoaldehyde is then oxidised to glycolic acid, glyoxylic acid and finally oxalic acid. While ethylene glycol itself causes intoxication, the accumulation of toxic metabolites is responsible for the potentially fatal acidosis and renal failure, which characterises ethylene glycol poisoning. Treatment of ethylene glycol poisoning consists of emergent stabilisation, correction of metabolic acidosis, inhibition of further metabolism and enhancing elimination of both unmetabolised parent compound and its metabolites. The prevention of ethylene glycol metabolism is accomplished by the use of antidotes that inhibit alcohol dehydrogenase. Historically, this has been done with intoxicating doses of ethanol. At a sufficiently high concentration, ethanol saturates alcohol dehydrogenase, preventing it from acting on ethylene glycol, thus allowing the latter to be excreted unchanged by the kidneys. However, ethanol therapy is complicated by its own inherent toxicity, and the need to carefully monitor serum ethanol concentrations and adjust the rate of administration. A recent alternative to ethanol therapy is fomepizole, or 4-methylpyrazole. Like ethanol, fomepizole inhibits alcohol dehydrogenase; however it does so without producing serious adverse effects. Unlike ethanol, fomepizole is metabolised in a predictable manner, allowing for the use of a standard, validated administration regimen. Fomepizole therapy eliminates the need for the haemodialysis that is required in selected patients who are non-acidotic and have adequate renal function.     

Mode of Action: Oxalate Crystal-Induced Renal Tubule Degeneration and Glycolic Acid-Induced Dysmorphogenesis—Renal and Developmental Effects of Ethylene Glycol

Ethylene glycol can cause both renal and developmental toxicity, with metabolism playing a key role in the mode of action (MOA) for each form of toxicity. Renal toxicity is ascribed to the terminal metabolite oxalic acid, which precipitates in the kidney in the form of calcium oxalate crystals and is believed to cause physical damage to the renal tubules. The human relevance of the renal toxicity of ethylene glycol is indicated by the similarity between animals and humans of metabolic pathways, the observation of renal oxalate crystals in toxicity studies in experimental animals and human poisonings, and cases of human kidney and bladder stones related to dietary oxalates and oxalate precursors. High-dose gavage exposures to ethylene glycol also cause axial skeletal defects in rodents (but not rabbits), with the intermediary metabolite, glycolic acid, identified as the causative agent. However, the mechanism by which glycolic acid perturbs development has not been investigated sufficiently to develop a plausible hypothesis of mode of action, nor have any cases of ethylene glycol-induced developmental effects been reported in humans. Given this, and the variations in sensitivity between animal species in response, the relevance to humans of ethylene glycol-induced developmental toxicity in animals is unknown at this time.     

Mode of action: oxalate crystal-induced renal tubule degeneration and glycolic acid-induced dysmorphogenesis--renal and developmental effects of ethylene glycol

Ethylene glycol can cause both renal and developmental toxicity, with metabolism playing a key role in the mode of action (MOA) for each form of toxicity. Renal toxicity is ascribed to the terminal metabolite oxalic acid, which precipitates in the kidney in the form of calcium oxalate crystals and is believed to cause physical damage to the renal tubules. The human relevance of the renal toxicity of ethylene glycol is indicated by the similarity between animals and humans of metabolic pathways, the observation of renal oxalate crystals in toxicity studies in experimental animals and human poisonings, and cases of human kidney and bladder stones related to dietary oxalates and oxalate precursors. High-dose gavage exposures to ethylene glycol also cause axial skeletal defects in rodents (but not rabbits), with the intermediary metabolite, glycolic acid, identified as the causative agent. However, the mechanism by which glycolic acid perturbs development has not been investigated sufficiently to develop a plausible hypothesis of mode of action, nor have any cases of ethylene glycol-induced developmental effects been reported in humans. Given this, and the variations in sensitivity between animal species in response, the relevance to humans of ethylene glycol-induced developmental toxicity in animals is unknown at this time.     

Rapid determination of ethylene glycol and glycolic acid in biological fluids

Ethylene glycol poisoning of companion animals is a common occurrence and is sometimes involved in human intoxication. Ethylene glycol is of limited toxicity, but the metabolites including glycolic acid are responsible for poisoning. Conventional treatment has employed substances to prevent alcohol dehydrogenase from metabolizing the ethylene glycol, but to be effective, therapy must begin within hours of ethylene glycol consumption. We describe a rapid (10 min) analysis of biological fluids for ethylene glycol and glycolic acid using isocratic HPLC, a refractive index detector, and a Waters fast fruit juice analytical column.     

Comparison of the metabolism of ethylene glycol and glycolic acid in vitro by precision-cut tissue slices from female rat, rabbit and human liver

1. The metabolism of [1,2-(14)C]-ethylene glycol and [1,2-(14)C]-glycolic acid was studied in vitro using precision-cut tissue slices prepared from the livers of female Sprague-Dawley rats, New Zealand white rabbits and humans. The time-course for production of metabolites formed from ethylene glycol at concentrations from 3 to 40 mM was determined to compare quantitatively the differences between species in the rates and amounts of formation of glycolic acid, the presumed developmental toxicant of ethylene glycol. The rates of metabolism of glycolic acid to glyoxylic acid at concentrations from 0.05 to 16 mM by liver tissue from the different species were also determined. The apparent V(max)/K(m) for the metabolic conversions of ethylene glycol to glycolic acid and for glycolic acid to glyoxylic acid in liver tissue from the different species were obtained. 2. There were qualitative differences in the metabolic profiles and quantitative differences in the formation of glycolic acid between the mammalian liver systems. There was an average of 10-fold less glycolic acid produced by liver slices from rabbits compared with rats. With the human liver, the formation of glycolic acid was not detectable using tissue from three of four human donors. A low level of glycolic acid was detected in one liver slice incubation from one of the four subjects, but only at one extended time point; glyoxylate was detected with liver slices from all four humans. 3. Liver slices prepared from female Sprague-Dawley rats, female New Zealand White rabbits and three female human subjects all metabolized glycolic acid to glyoxylic acid. Human liver tissue was the most effective at further metabolizing glycolic acid to glyoxylic acid. The ratios of V(max)/K(m), representing the relative clearance of glycolic acid from liver tissue, were approximately 14:9:1 for human, rat and rabbit liver, respectively. 4. Precision-cut liver slices maintained in dynamic organ culture are good predictors of metabolism by liver tissue in vivo. The results of the present study therefore indicate that levels of glycolic acid, if formed in vivo, following exposures to similar concentrations of ethylene glycol, would be lower in humans than in rabbits and rats.     

Comparison of the metabolism of ethylene glycol and glycolic acid in vitro by precision-cut tissue slices from female rat,rabbit and human liver

1.?The metabolism of [1,2-¹⁴C]-ethylene glycol and [1,2-¹⁴C]-glycolic acid was studied in vitro using precision-cut tissue slices prepared from the livers of female Sprague—Dawley rats, New Zealand white rabbits and humans. The time-course for production of metabolites formed from ethylene glycol at concentrations from 3 to 40 mM was determined to compare quantitatively the differences between species in the rates and amounts of formation of glycolic acid, the presumed developmental toxicant of ethylene glycol. The rates of metabolism of glycolic acid to glyoxylic acid at concentrations from 0.05 to 16 mM by liver tissue from the different species were also determined. The apparent V_maJK_m for the metabolic conversions of ethylene glycol to glycolic acid and for glycolic acid to glyoxylic acid in liver tissue from the different species were obtained.

2.?There were qualitative differences in the metabolic profiles and quantitative differences in the formation of glycolic acid between the mammalian liver systems. There was an average of 10-fold less glycolic acid produced by liver slices from rabbits compared with rats. With the human liver, the formation of glycolic acid was not detectable using tissue from three of four human donors. A low level of glycolic acid was detected in one liver slice incubation from one of the four subjects, but only at one extended time point; glyoxylate was detected with liver slices from all four humans.

3.?Liver slices prepared from female Sprague—Dawley rats, female New Zealand White rabbits and three female human subjects all metabolized glycolic acid to glyoxylic acid. Human liver tissue was the most effective at further metabolizing glycolic acid to glyoxylic acid. The ratios of F"_max/-/C_m, representing the relative clearance of glycolic acid from liver tissue, were approximately 14:9:1 for human, rat and rabbit liver, respectively.

4.?Precision-cut liver slices maintained in dynamic organ culture are good predictors of metabolism by liver tissue in vivo. The results of the present study therefore indicate that levels of glycolic acid, if formed in vivo, following exposures to similar concentrationsof ethylene glycol, would be lower in humans than in rabbits and rats.     

Ethylene glycol toxicity: the role of serum glycolic acid in hemodialysis.

OBJECTIVE: To correlate serum glycolic acid levels with clinical severity and outcome in ethylene glycol poisoning and to determine if glycolic acid levels are predictive of renal failure and the need for hemodialysis. METHODS: We measured serum ethylene glycol and glycolic acid levels by gas chromatography/mass spectrometry for 41 admissions (39 patients) for ethylene glycol ingestion and performed retrospective chart reviews. RESULTS: Eight patients died, all of whom developed acute renal failure. Of the survivors, 15 also developed acute renal failure, whereas 18 did not. Of those with normal renal function, 8 had glycolic acid levels below detection limits (< 0.13 mmol/L) despite ethylene glycol levels as high as 710 mg/dL; 7 of these patients coingested ethanol. Pertinent initial laboratory data for each group are as follows (mean; range): Deceased: pH 6.99 (6.82-7.22); bicarbonate, 4.8 mmol/L (2-9); anion gap, 28.6 mmol/L (24-40); glycolic acid, 23.5 mmol/L (13.8-38.0); ethylene glycol, 136.5 mg/dL (6-272). Survived/acute renal failure: pH 7.07 (6.75-7.32); bicarbonate, 5.6 mmol/L (1-12); anion gap, 28.7 mmol/L (18-41); glycolic acid, 20.2 mmol/L (10.0-30.0); ethylene glycol, 238.8 mg/dL (12-810). No acute renal failure with glycolic acid > 1.0 mmol/L: pH 7.29 (7.12-7.46); bicarbonate, 14.7 mmol/L (4-23); anion gap, 16.5 mmol/L (10-26); glycolic acid, 6.8 mmol/L (2.6-17.0); ethylene glycol, 269.1 mg/dL (6-675). No acute renal failure with glycolic acid < 1.0 mmol/L: pH 7.41 (7.38-7.47); bicarbonate, 23.4 mmol/L (17-25); anion gap, 11.8 mmol/L (8-18); glycolic acid, 0.1 mmol/L (0-0.66); ethylene glycol, 211 mg/dL (8-710). The mean time postingestion to admission generally correlated with severity as follows: deceased, > or = 10.4 h; survived/acute renal failure, > or = 9.9 h; no acute renal failure with glycolic acid > 1.0 mmol/L, > or = 6.2 h; no acute renal failure with glycolic acid < 1.0 mmol/L, > or = 3.7 h. Hematuria was more prevalent than oxaluria (86% and 41%, respectively), but neither was individually predictive of acute renal failure. Good correlations were found between glycolic acid levels and anion gap (r2 = 0.7724), pH (r2 = 0.7921), and bicarbonate (r2 = 0.6579); poor correlations (r2 < 0.0023) occurred between ethylene glycol levels and glycolic acid, pH, anion gap, and bicarbonate. Measured ethylene glycol values were highly correlated with ethylene glycol values calculated from the osmolal gap (r2 = 0.9339), but the latter overestimates the true value by about 7%, on average. An initial glycolic acid level > or = 10 mmol/L predicts acute renal failure with a sensitivity of 100%, a specificity of 94.4%, and an efficiency of 97.6%. Ethylene glycol levels are not predictive of acute renal failure or central nervous system manifestations of toxicity. If only ethylene glycol values are available (measured or calculated), an initial anion gap > 20 mmol/L is 95.6% sensitive and 94.4% specific for acute renal failure when ethylene glycol is present. Likewise, initial pH < 7.30 is 100% sensitive and 88.5% specific for acute renal failure. CONCLUSION: We propose glycolic acid > 8 mmol/L as a criterion for the initiation of hemodialysis in ethylene glycol ingestion. Patients with glycolic acid < 8 mmol/L probably do not need dialysis, regardless of the ethylene glycol concentration, when metabolism of ethylene glycol is therapeutically inhibited. In the absence of glycolic acid values, an anion gap > 20 mmol/L or pH < 7.30 predicts acute renal failure.     

Incorporation of therapeutic interventions in physiologically based pharmacokinetic modeling of human clinical case reports of accidental or intentional overdosing with ethylene glycol.

Although occupational uses of the high production volume (HPV) chemical ethylene glycol (EG) have not been associated with adverse effects, there are case reports where humans have either intentionally or accidentally ingested large quantities of EG, primarily from antifreeze. The acute toxicity of EG can proceed through three stages, each associated with a different metabolite: central nervous system depression (ethylene glycol), cardiopulmonary effects associated with metabolic acidosis (glycolic acid), and ultimately renal toxicity (oxalic acid), depending on the total amounts consumed and the effectiveness of therapeutic interventions. A physiologically based pharmacokinetic (PBPK) model developed in a companion paper (Corley et al., 2005). Development of a physiologically based pharmacokinetic model for ethylene glycol and its metabolite, glycolic acid, in rats and humans. Toxicol. Sci., in press 2005) was refined in this study to include clinically relevant treatment regimens for EG poisoning such as hemodialysis or metabolic inhibition with either ethanol or fomepizole. Such modifications enabled the model to describe data from several human case reports, confirming the ability of the previous model to describe the pharmacokinetics of EG and its metabolite, glycolic acid, in humans across a broad range of doses and multiple exposure routes. By integrating the case report data sets with controlled studies in this PBPK model, it was demonstrated that fomepizole, if administered early enough in a clinical situation, can be more effective than ethanol or hemodialysis in preventing the metabolism of EG to more toxic metabolites. Hemodialysis remains an important option, however, if treatment is instituted after a significant amount of EG is metabolized or if renal toxicity has occurred.     

Ethylene glycol ingestion treated only with fomepizole

Introduction

Ethylene glycol is a widely used chemical that is capable of causing significant injury if ingested. Treatment for ethylene glycol poisoning typically includes basic supportive care, alcohol dehydrogenase inhibition, and hemodialysis. Recent data have suggested that hemodialysis may not be necessary for cases of ethylene glycol poisoning that can be treated with fomepizole as blocking therapy before acidosis or renal dysfunction develops.

Case Report

A 33-year-old man presented to the emergency department 1 hour after drinking approximately 1/2 gallon of ethylene glycol antifreeze and an unknown quantity of beer. On arrival he was mildly inebriated but otherwise displayed no other features of ethylene glycol poisoning. Fomepizole therapy was initiated and initial laboratory studies later revealed an osmol gap of 157 mOsm and an ethylene glycol concentration of 706 mg/dL. Nephrology and toxicology services were consulted. Over the next 3 days, fomepizole therapy was continued while the patient’s acid-base status and renal function were closely monitored. No evidence of acid-base abnormalities or renal impairment was ever observed and the patient was discharged to psychiatric care on the fourth hospital day.

Discussion

This report describes the case of a patient who presented soon after a massive ingestion of ethylene glycol with very high serum concentrations. He was successfully treated using fomepizole and basic supportive care. Our patient developed neither renal insufficiency nor metabolic acidosis. His concomitant ethanol consumption, early presentation, and treatment likely contributed to his favorable outcome. This case report underscores the effectiveness of supportive care and fomepizole in the treatment of ethylene glycol poisoning.     

Predictors of Ethylene Glycol Ingestion Cases Called into a Regional Poison Center

Poison center consultations for potential toxic alcohol poisonings are challenging because blood levels are typically not immediately available. The primary objective of this study was to determine whether readily obtainable laboratory values can be used to accurately and rapidly diagnose these poisonings. Over a 15-month period, patients with a history of toxic alcohol ingestion or a metabolic acidemia (pH?≤?7.30 or serum bicarbonate ≤?18 mEq/L) that prompted a poison center consultation were enrolled. A predictive logistic regression model was used to assess the combined ability of serum pH, calcium, osmolar gap, and anion gap levels to predict a final diagnosis of toxic alcohol poisoning. There were 102 subjects included in the analysis. A total of 44% (45/102) patients had a final diagnosis of ethylene glycol (EG) poisoning. Higher levels of calcium, osmolar gap, and anion gap were independently associated with statistically significant or marginally significant increases in the odds of a final diagnosis of EG poisoning. The c-index was estimated at 0.81, indicating that the model showed a reasonable ability to discriminate EG cases from others. The final model had a sensitivity and specificity of 78% and 89%, respectively, and positive and negative predictive values of 84% and 83% respectively. The combination of elevated calcium, osmolar gap, and anion gap is associated with a high likelihood of EG poisoning, but clinician gestalt is still essential for its diagnosis. Further refinement of the model is needed.     

Adolescent poisoning: a comparison of accidental and intentional exposures

The fact that intentional drug and toxic substance use/abuse by adolescents has dramatically increased during the past 2 decades often overshadows the knowledge that adolescents also suffer accidental poisonings as well. A 1-year retrospective analysis of 1,879 poison exposures involving children 13 to 17 years of age revealed 894 (47.6%) were due to accidental circumstances and 945 (50.2%) were intentional in nature. Nonpharmaceuticals were involved in 63.5% of all accidental adolescent poisonings versus 36.5% involving various drugs. Intentional nonpharmaceutical exposures were 17.5% compared to total intentional adolescent poisonings, while 82.5% involved drugs. Site of exposure was the child's own home in 1,252 (66.7%) cases, school in 201 (10.8%), the workplace in 35 (1.9%), and other/unknown sites accounted for 387 (20.6%) poisonings. Poisoning by ingestion accounted for 1,408 (74.9%) of the adolescent exposures, inhalations 147 (7.8%), ocular 219 (11.5%), and dermal 110 (5.8%). Management at the nearest health care facility (HCF) was necessary in 1,252 (66.6%) of the poisonings versus 627 (33.4%) who were treated in non-HCF environments. Regional poison centers must be cognizant that accidental as well as intentional poisoning can occur with adolescents. Distinct viable prevention strategies should be developed to address these problems.     

Patterns of animal poisonings reported to the Texas Poison Center Network: 1998-2002

A portion of calls handled by poison centers involve poisonings of animals; however, information on such calls is limited. This study used data from poison centers in Texas collected during 1998-2002 to document the epidemiology of animal poisoning calls. There were a total of 24,467 animal poisoning calls, representing 2.0% of all calls. Dogs were affected in 87% of the calls and cats in 11%. The exposures were unintentional in 99% of the cases, occurred via ingestion in 95% and involved dermal exposure in 5% of the cases. Exposures occurred at the owner's own residence 91% of the time and were handled outside of health care facilities 61% of the time. The outcome involved no clinical effect for 60% of the cases involving dogs and 39% of the cases involving cats. Reported exposures occurred more often during the summer, and the most frequently reported exposures involved pesticides and plants. These findings were consistent with the limited reports from on poison center regarding animal poisonings.     

The experience of starting a poison control centre in Africa--the Ghana experience

The need for a poison centre in Ghana has been well demonstrated over the years as evidenced by the occurrence of a variety of cases of poisoning. Important causes are accidental poisoning from mishandling of pesticides, accidental poisoning among children from kerosene and pesticide' ingestion due to unsafe storage methods in the home, use of herbal potions of unknown composition, overdoses of certain pharmaceuticals for illegal abortion, and accidental food poisonings. Bites from venomous animals particularly snakes are also common. Though preparations toward the establishment of a poison control centre started in mid 1999, it was not until early 2002 that the operations of a modest information centre commenced. Major roles the centre are currently performing include providing: an information service for health professionals on management advice in cases of poisoning; training for primary health personnel in the management of common poisonings; training for agricultural personnel in prevention and first aid management of pesticide poisoning; public awareness education and information programmes for prevention of poisoning. Some of the important challenges being faced include ensuring adequate sensitization on the need for centers particularly among health professionals, difficulties in acquiring adequate numbers of and appropriate training for staff of the centre, dedicated phone lines, literature and timely acquisition of toxicological data-bases. Others are poor networking among centers in the region and the absence of clinical and laboratory toxicology services dedicated to managing poisonings. The key lessons learned include the need for multi-sectoral involvement and support from the onset, the need to learn from experiences of established centers and the need to model requirements to suit local conditions without compromising the effectiveness of services.     

Ethylene glycol generates free radical metabolites in rats: an ESR in vivo spin trapping investigation

Ethylene glycol, best known as antifreeze, is most often ingested accidentally or as a substitute for alcochol by chronic alcohol abusers. The toxicity of ethylene glycol poisoning is due to its toxic metabolites rather than to ethylene glycol itself. In this study, electron spin resonance (ESR) spectroscopy has been used to study free radical generation in rats by acute ethylene glycol poisoning. The radical spin trapping technique was applied where the spin trapping agent alpha-(4-pyridyl-1-oxide)-N-tert-butylnitrone (POBN) reacted with free radical metabolites to form radical adducts in vivo. The radical adducts from ethylene glycol intoxication were detected in both the bile and urine samples of male Sprague-Dawley rats. The identification of the POBN-(.)[(13)C]ethylene glycol radical adduct provides for the first time direct ESR evidence for the generation of the ethylene glycol-derived radicals during acute intoxication by ethylene glycol, suggesting a new metabolic pathway. Simultaneous administration of alcohol dehydrogenase inhibitor 4-methylpyrazole with ethylene glycol resulted in an enhanced free radical generation in the bile. This report is the first evidence of ethylene glycol free radical metabolism in rats with acute ethylene glycol intoxication.     

Diagnostic data in clinical toxicology--should we use a Bayesian approach?

A number of toxidromes (toxicology syndromes) have been described for various poisonings and are promoted as a means of reaching a diagnosis in patients presenting with unknown poisonings. Many are based entirely on deductive reasoning from the known pharmacological effects of these drugs rather than on documented clinical experience. In this paper, we used our database, where we have recorded clinical signs on presentation in unselected poisonings to explore how clinical signs actually alter the odds of ingestion of different poisons. Many signs substantially altered the list of drugs likely to have been ingested. We found that the most important factor determining whether an unconscious patient had ingested a particular drug was how frequently that drug was taken generally (i.e., the a priori probability), rather than the presence of any particular physical sign. It also follows that our (or anyone else's) intuitive or deductive approach to diagnosis, derived from experience, will not necessarily be very useful at another place where predominantly different drugs are involved in poisoning. Our data were used to derive odds ratios as a measure of the strength of association of physical signs or investigations with ingested poisons. These can be used to develop simple diagnostic algorithms orflow charts to identify the most likely drugs ingested, or using more complicated programming, could also be used to calculate the precise probability of different drug-ingestion using Bayes' Theorem. The usefulness (i.e., external validity) of clinical research from other centers can also be determined.     

Acute actinic cheilitis-like chemical irritant reaction following accidental contact with ethylene glycol-favorable response to topical 1% pimecrolimus cream: a case report

Ethylene glycol is a colorless, odorless, nonvolatile, water-soluble fluid, mainly used as automobile antifreeze and coolant. This substance is a frequent culprit in accidental and intentional poisonings. Although potentially fatal systemic consequences of ethylene glycol ingestion are well known, local adverse effects through brief skin and mucosa contact with ethylene glycol have been rarely reported. Herein we report a patient with accidental ethylene glycol contact to the lower lip, who presented with acute, manifest, actinic cheilitis-like chemical irritant reaction and favorably responded to topical pimecrolimus 1% cream.     

Considerations for the treatment of ethylene glycol poisoning based on analysis of two cases

The clinical picture as well as the principles of treatment in ethylene glycol poisoning differ with the time after ingestion. These time-related differences are illustrated by two case reports. During the first hours of ethylene glycol poisoning, the patient suffers from drunkenness, vomiting and somnolence due to the intoxicant effect of ethylene glycol on the central nervous system. In the following hours a poisoning with glycolate and oxalate develops, with increasing acidosis, renal and brain damage. A patient admitted within a few hours of an overdose, with no or only slight metabolic acidosis, may be successfully treated with ethanol. If the serum concentration of ethylene glycol is very high, hemodialysis may be deferred until the necessary staff and equipment are available. If the patient is admitted with severe metabolic acidosis, hemodialysis must be started immediately. The need for ethanol administration during hemodialysis merits reevaluation.     

Effects of ethylene glycol and metabolites on in vitro development of rat embryos during organogenesis

The aim of this study was to investigate in vitro the relative impact of ethylene glycol, a major industrial chemical, and its individual metabolites on the embryonic development of rats. Rat whole embryos were exposed for 48 h (day 9.5–11.5 of gestation) to ethylene glycol (EG) and its metabolites glycolaldehyde (GAl), glycolic acid (GA), glyoxylic acid (GXA), glyoxale (GXAl) and oxalic acid (OXA) at increasing concentrations. Embryotoxic concentrations were achieved within the following range: ethylene glycol (100–200 m ), glycolic acid (3 m ), glyoxal (6 m ), oxalic acid (1–3 m ), glyoxylic acid (0.3–1 m ), glycolaldehyde (0.1–0.2 m ). The pattern of dysmorphogenesis with all compounds including EG showed a general embryotoxicity with diffusely distributed cell necroses with no specific target tissues selectively affected. The results obtained in this study emphasize the hypothesis that the metabolites and not ethylene glycol itself are responsible for the embryotoxicity of ethylene glycol in rats.     

A retrospective evaluation of analgesic exposures from Izmir, Turkey

The objective of this study is to analyze exposures concerning analgesics that were reported to Dokuz Eylul University Drug and Poison Information Center (DPIC) and admitted to the Department of Emergency Medicine in Dokuz Eylul University Hospital (EMDEU) between 1993 and 2004. Demographics of the patients, characteristics of analgesic exposures, performed treatment attempts and outcome of the poisoned patients were recorded on standard data forms and were then entered into a computerized database program. Statistical analysis was performed by using the chi-square test. The DPIC recorded 55 962 poisoning calls, 48 654 (86.9%) of them related to medicines. Analgesics accounted for 16.3% (7 939 cases) of all medicine-related exposures; among them 446 exposures were admitted to EMDEU. More than half of the analgesic exposure calls and admitted cases involved adults (55.9%, 4 440). Females dominated in all age groups (70.3%, 5 578). Mean age was 20.2 +/- 11.8. The most involved analgesics were paracetamol (47.9%), propionic acid derivatives (16.1%) and salicylates (13.7%). Most of the poisonings were intentional (75.1%), especially in 19-29 years age group of adults and 13-18 years age group of children. Most of the patients reported to DPIC and admitted to EMDEU were asymptomatic (84.4% and 54.7%, respectively). Gastrointestinal decontamination methods were performed more frequently for admitted poisoning cases before hospital admission than reported poisoning cases (61% vs. 23%). Paracetamol ingestion was the most common cause of analgesic exposures reported to our DPIC. Most of the analgesic exposures reported to DPIC were asymptomatic or mild. DPICs have an important role for the referral of analgesic exposures without unnecessary gastrointestinal decontamination procedures.