Use of Intravenous Lipid Emulsion Therapy and Insulin in a Case of Tarka Intoxication.

INTRODUCTION: Tarka (trandolapril/verapamil hydrohloride extended-release) is a fixed-dose combination antihypertensive drug formed from verapamil hydrochloride and trandolapril. Toxicologic manifestations of Tarka overdose are altered mental status, bradycardia, hypotension, atrioventricular block (first-degree), hyperglycemia, metabolic acidosis, and shock. CASE PRESENTATION: We report a case of Tarka toxicity in a 2-year-old girl who presented with altered mental status, cardiogenic shock, hypotension, bradycardia, severe metabolic acidosis, hyperglycemia, and first-degree atrioventricular block. We started fluid resuscitation, epinephrine, norepinephrine, and insulin. Because of the patient's hyperlactatemia and hypotension despite standard therapies, we initiated intravenous lipid emulsion (ILE) therapy, after which her condition improved promptly. DISCUSSION: Tarka overdose may be life-threatening as it can cause cardiogenic shock. In our patient, the regression of lactate elevation in a short time with ILE therapy and the improvement of her general condition highlight the importance of ILE. CONCLUSIONS: ILE is an alternative treatment method for acute lipophilic drug intoxications, such as Tarka.

Detection of intact insulin analogues in post-mortem vitreous humour-Application to forensic toxicology casework.

The application of proteomic techniques to forensic science widens the range of analytical capabilities available to forensic laboratories when answering complex toxicology problems. Currently, these techniques are underutilised in post-mortem toxicology because of the historic focus on smaller (<1,000 amu) drug molecules. Definitive confirmation of an insulin overdose by analysis of post-mortem biological matrices is rare and challenging, however can assist coronial investigations pertaining to accidental or intentional overdoses in both diabetic and nondiabetic populations. A semiautomated micro-solid phase extraction paired with mass spectrometry-based insulin methodology was developed and validated for routine use in a Forensic Coronial Toxicology Laboratory. This resulting work reports the first Australian cases where synthetic insulins were confirmed by mass spectrometry in the vitreous humour of Type 1 diabetics who intentionally or accidentally overdosed on their prescription medication glargine and aspart. The detection of glargine M1 in Case 1, aspart in Case 2 and glargine M1 was indicated in Case 3. This paper highlights advancements in forensic coronial toxicology and the promising potential of proteomic analysis in a forensic context.

Is insulin intoxication still the perfect crime? Analysis and interpretation of postmortem insulin: review and perspectives in forensic toxicology.

Insulin is an anabolic hormone essential to glucose homeostasis. Insulin therapy, comprising human insulin (HI) or biosynthetic analogs, is critical for the management of type-1 diabetes and many of type-2 diabetes. However, medication error including non-adapted dose and confusion of insulin type, and misuse, such as massive self-administration or with criminal intent, can have lethal consequences. The aim of this paper is to review the state of knowledge of insulin analysis in biological samples and of the interpretation of insulin concentrations in the situation of insulin-related death investigations. Analytic aspects are considered, as quantification can be strongly impacted by methodology. Immunoanalysis, the historical technique, has a prominent role due to its sensitivity and ease of implementation. Recently, liquid chromatography coupled to mass spectrometry has provided indispensable selectivity in forensic contexts, distinguishing HI, analogs, and degradation products. We review the numerous antemortem (dose, associated pathology, injection-to-death interval, etc.) and postmortem parameters (in corpore degradation, in vitro degradation related to hemolysis, etc.) involved in the interpretation of insulin concentration. The interest and limitations of various alternative matrices providing a valuable complement to blood analysis are discussed. Vitreous humor is one of the most interesting, but the low diffusion of insulin in this matrix entails very low concentrations. Injection site analysis is relevant for identifying which type of insulin was administered. Muscle and renal cortex are matrices of particular interest, although additional studies are required. A table containing most case reports of fatal insulin poisoning published, with analytical data, completes this review. A logic diagram is proposed to highlight analytical issues and the main parameters to be considered for the interpretation of blood concentrations. Finally, it remains a challenge to provide reliable biological data and solid interpretation in the context of death related to insulin overdose. However, the progress of analytical tools is making the "perfect crime" ever more difficult to commit.

A Case Involving Massive Insulin Overdose: Direct and Indirect Conditions Requiring Extended Management of Serum Potassium.

BACKGROUND Insulin lowers not only blood glucose levels but also serum potassium levels by driving potassium into the cells. Hypokalemia can occur during aggressive treatment of hypoglycemia in patients with insulin overdose and is a well-documented clinical phenomenon; however, there are no studies describing delayed hyperkalemia occurring after initial treatment in patients with insulin overdose. CASE REPORT A 23-year-old male with a history of type 2 diabetes mellitus and self-medicating with insulin, attempted suicide by subcutaneously injecting 2100 units of insulin. He was admitted to our emergency department due to recurrent hypoglycemia. Continuous administration of 50% glucose and potassium via a central venous catheter was performed to maintain his glucose levels above 80 mg/dL and serum potassium level between 3.5 and 4.0 mEq/L. Because his serum potassium level exceeded 4.5 mEq/L at day 3 after admission, the dosage was adjusted accordingly. After his serum potassium level declined to 3.0 mEq/L, his potassium level abruptly increased to 6.0 mEq/L at day 5 after admission. The patient was placed on a potassium-restricted diet and administered furosemide. Potassium infusion was also discontinued. After serum potassium levels returned to the normal range without interventional therapies, the patient was discharged to home on day 14. CONCLUSIONS In cases of high-dose insulin overdose, management of hyperkalemia following recovery from hypoglycemia is a critical aspect of patient management. Conservative administration of potassium to correct initial hypokalemia may be considered in patients with high-dose insulin overdose.

Pharmacokinetics of insulin disappearance after massive overdosing.

Long-term glucose supplementation is required to prevent hypoglycemia after massive insulin overdosing. We fitted the blood insulin concentration-time profile to the model: I = A·exp(-a·t) + B·exp(-b·t), where I (µU/mL) is the serum/plasma insulin concentration, A (µU/mL) and B (µU/mL) are the peak insulin concentrations of each component, a (time-1) and b (time-1) are the time constants of each component, and t (h) is the time elapsed from the peak of blood insulin level. Additional components were considered as needed. Patient 1 had auto-injected 600 U NovoRapid® 30Mix, and Patient 2 had auto-injected 300 U Novolet®R (regular) and 1,800 U NovoLet®N (NPH). We used the disappearance of therapeutic doses of the respective insulin in healthy individuals as controls, and we obtained parameters by Excel solver. In Patient 1, the parameter values were A = 1490.04 and a = 0.15 for insulin aspart and B = 60.66 and b = 0.04 for protaminated aspart. In Patient 2, the values were A = 784.45 and a = 0.38 for regular insulin and B = 395.84 and b = 0.03 for NPH. Compared with controls, the half-lives (t1/2) for insulin aspart and protaminated aspart were 4 and 2 times longer, respectively, in Patient 1. In Patient 2, the t1/2 for regular and NPH insulin were 2 and 7 times longer than those in the controls, respectively. In conclusion, the t1/2 for insulin was elongated 2 to 7 times after massive overdosing, explaining why glucose supplementation is needed for long periods in these cases.

A Systematic Review on Insulin Overdose Cases: Clinical Course, Complications and Treatment Options.

A large overdose of insulin is a serious health matter. Information concerning administration and duration of intravenous (IV) glucose, other treatment options or complications besides hypoglycaemia following large insulin overdoses is not readily apparent from the literature. A systematic search, compilation and review of case reports on insulin overdoses, published 1986-2017, was performed in PubMed, EMBASE, Cochrane and PROSPERO databases. Of 1523 published articles, 45 cases of insulin overdoses were included with a total median insulin dose of 900 international units (IU) (range 26-4800 IU). Hospitalization occurred in 44 cases with a median hospitalization duration of 94 hr (range 12-721 hr), and one-third (n = 15) admitted to the intensive care unit. First-line treatment was IV glucose treatment in 95% of cases. Treatment options besides IV glucose that were reported beneficial included glucagon IV or intramuscular (IM), octreotide IV or IM, surgical excision, hydrocortisone IV and oral intake of complex carbohydrates. Prevalent complications were intermittent cerebral impairment (73%), hypokalaemia (49%), other electrolyte disturbances (42%), and hepatic disturbances (7%) and cardiac toxicity (e.g. cardiac arrhythmia) (9%). Long-term consequences were one case of lasting hypoglycaemic encephalopathy and one death. In conclusion, following large insulin overdoses, in-hospital admission and treatment with IV glucose may be needed for up to a week. Monitoring of electrolytes and hepatic and cardiac functions seems important. Several experimental treatment options may be considered in addition to glucose administration. With appropriate pre- and in-hospital treatment, cases with severe hypoglycaemia and neurologic complications may have a favourable outcome.

Forensic aspects of homicides by insulin overdose.

Analysis of homicidal insulin overdose is a challenging task in forensic practice because of the difficulties in toxicological analysis as well as the elusive pathologic changes. We performed a detailed histopathologic examination on four autopsy cases involving insulin homicide, using H&E, immunohistochemistry (IHC) and immunofluorescence assays. Severe reactive astrocyte proliferation was obvious in the white matter of the cerebrum, corpus callosum, cerebellum and brain stem, especially in subcortical regions. We found a statistically significant increase in the number and total area of reactive astrocytes compared with controls (p<0.001). Insulin was detected at the injection sites of subcutaneous soft tissues by using IHC, luminescence immunoassay and immunofluorescence. Most insulin deposits were located in the gaps between adipocytes, and a few deposits were located in peripheral nerves and inflammatory cells. We also detected protamine in the skin tissues in two of the four cases. Our study revealed that the presence of insulin and/or protamine at the injection sites, along with severe reactive astrocyte proliferation, could help diagnose insulin overdose.

Treatment of sulfonylurea and insulin overdose.

The most common toxicity associated with sulfonylureas and insulin is hypoglycaemia. The article reviews existing evidence to better guide hypoglycaemia management. Sulfonylureas and insulin have narrow therapeutic indices. Small doses can cause hypoglycaemia, which may be delayed and persistent. All children and adults with intentional overdoses need to be referred for medical assessment and treatment. Unintentional supratherapeutic ingestions can be initially managed at home but if symptomatic or if there is persistent hypoglycaemia require medical referral. Patients often require intensive care and prolonged observation periods. Blood glucose concentrations should be assessed frequently. Asymptomatic children with unintentional sulfonylurea ingestions should be observed for 12 h, except if this would lead to discharge at night when they should be kept until the morning. Prophylactic intravenous dextrose is not recommended. The goal of therapy is to restore and maintain euglycaemia for the duration of the drug's toxic effect. Enteral feeding is recommended in patients who are alert and able to tolerate oral intake. Once insulin or sulfonylurea-induced hypoglycaemia has developed, it should be initially treated with an intravenous dextrose bolus. Following this the mainstay of therapy for insulin-induced hypoglycaemia is intravenous dextrose infusion to maintain the blood glucose concentration between 5.5 and 11 mmol l(-1) . After sulfonylurea-induced hypoglycaemia is initially corrected with intravenous dextrose, the main treatment is octreotide which is administered to prevent insulin secretion and maintain euglycaemia. The observation period varies depending on drug, product formulation and dose. A general guideline is to observe for 12 h after discontinuation of intravenous dextrose and, if applicable, octreotide.

Fatal Insulin Overdoses: Case Report and Update on Testing Methodology.

Suicidal insulin overdoses are an under-recognized and uncommon cause of death, often relying on scene and nonspecific autopsy findings. Here, we present a case report of a fatal exogenous insulin overdose in a patient with type 1 diabetes. In our case, there were no contributory autopsy findings; however, serum analog aspart insulin levels were c. 10× the predicted therapeutic upper limit (4000, reference 6.6-55 uU/mL), which correlated with scene findings. This was specifically determined by a newly developed immunocapture liquid chromatography-tandem mass spectrometry assay, able to discriminate between various synthetic insulin analogs. Total insulin levels by immunoassay were highly elevated on the Siemens Advia Centaur, but not the Roche platforms (4741 vs. 5.2 uU/mL, respectively), showing variable sensitivity of detection within the same analog depending on assay. We discuss the prevalence and features to look for at autopsy in these types of cases. Additionally, analytical options for testing insulin levels, including new methodologies, guidance on collection of samples, as well as an outline of available historical reference range data are discussed.

[Research Progress of the Death Caused by Insulin Intoxication].

In recent years, with the sustained increase of the incidence of diabetes in humans and the wider use of exogenous insulin, the cases of inappropriate use and overdose of insulin is growing, even the cases of suicide and homicide using insulin. Through searching the literature at home and abroad about the mechanism, clinical and case report of poisoning and death caused by insulin intoxication, this paper reviews the mechanism, clinical manifestations, pathological changes, and forensic examination.

Research Progress of the Death Caused by Insulin Intoxication / 法医学杂志

In recent years, with the sustained increase of the incidence of diabetes in humans and the wider use of exogenous insulin, the cases of inappropriate use and overdose of insulin is growing, even the cases of suicide and homicide using insulin. Through searching the literature at home and abroad about the mechanism, clinical and case report of poisoning and death caused by insulin intoxication, this paper reviews the mechanism, clinical manifestations, pathological changes, and forensic examination.

Prolonged bilateral reactive miosis as a symptom of severe insulin intoxication.

BACKGROUND: Miosis occurs following exposure to toxins that decrease the sympathomimetic tone, increase the cholinergic tone, or exert sedative-hypnotic effects, but has not been reported in insulin poisoning. CASE REPORT: A 64-year- old woman without co-morbidities was found unconscious next to an empty insulin pen. Her Glasgow Coma Scale was 3 with absent reflexes, bilateral reactive miosis, and injection marks across the abdominal wall. The patient was endotracheally intubated, mechanically ventilated, and transferred to this hospital. At admission, the blood glucose level was 34 mg/dL. Glasgow Coma Scale remained at 3, with persistent bilateral reactive miosis. The toxicology screening was negative for ethanol, barbiturates, tricyclic antidepressants, phenothiazines, amphetamines, cannabinoids, salicylates, acetaminophen, and cocaine. Cranial computed tomography with angiography and magnetic resonance imaging (MRI) did not show any structural brain lesions. Intravenous glucose was continued at 6-14 g/h for 3 days. On repeated neurological examinations, the patient remained deeply comatose, with partial loss of cranial nerve function. Bilateral reactive miosis persisted for 4 days. From day 5 on, the patient awoke progressively. At discharge, the patient was fully alert and orientated, without a focal neurological deficit. CONCLUSIONS: Prolonged bilateral reactive miosis can be a clinical symptom accompanying metabolic encephalopathy in severe insulin poisoning. Functional impairment of the pons due to relative hypoperfusion during hypoglycemia may serve as a reasonable pathophysiologic explanation for this phenomenon.

[Non usual cases of hypoglycaemia--hypoglycaemia factitia]. / Neobvyklé prípady hypoglykémie--hypoglycaemia factitia.

Hypoglycaemia factitia means also in recent time serious diagnostic and therapeutic problem in medical clinical practice, whereby often repeating episodes of serious hypoglycaemia in patients with diabetes mellitus, but also in patients without diabetes mellitus could be very difficult do resolve. First unsuccessful diagnosis implicit from wrong chose of examination algorithm, can lead to unidentified surgical interventions as are laparotomy and pancreatectomy, respectively. Hypoglycaemia factitia is considered to be one of many manifestations of so called Münchhausen's syndrome for that is typical acting of diabetic patient with goal to intentionally making hypoglycaemia or within suicidal attempt of patient on the basis psychological disease with intention to attract attention of surrounding community to himself due to application of insulin or sulfonylurea drugs. Diagnostic and therapeutic process could be in the case of hypoglycaemia factitia extremely difficult as from time side, than from health and also from economical side and that why necessary to approach with maximum responsibility.

Demographics and outcome of unintentional insulin overdoses managed by three poison centers.

UNLABELLED: Insulin dosing errors are one of the most dangerous medication issues due to the risk of profound hypoglycemia. The incidence of insulin dosing errors is increasing and there is no standard of care for management location. OBJECTIVE: To determine the types of insulin, follow-up time, number of phone calls, incidence of hypoglycemia, and case outcomes for unintentional insulin overdoses managed by Poison Centers (PCs). METHODS: Observational case series: records of patients with unintentional injected insulin errors from three PCs over a 22-month period were manually reviewed for insulin type, management site, time of exposure, insulin dose, number of calls, presence of hypoglycemia, and case outcome. RESULTS: There were 642 cases: 97.5% occurred in the home and the majority of patients (77.3%) were managed on site with only 17.4% resulting in Emergency Department treatment. Clinical or numerical (blood sugar < 60 mg/dL) hypoglycemia occurred 15.9% (n = 102) of the time in all cases, with 6.9% (n = 41) of cases having numerical hypoglycemia. The median insulin dose when known was 40 Units, with short-acting insulin making up the majority of cases (64.3%) with 13.8% of cases having a dose error of 80 or more units. The average duration of follow-up was 6.9 h. The frequency of hypoglycemia (clinical or numerical) did not differ between short and non-short duration insulin cases (15.7% vs. 16.9%, n = 65 vs. 37, p = 0.91), did not differ with cases receiving more than 50 Units of insulin (14.9% vs. 16.7%, n = 29 vs. 73, p = 0.64), and did not differ between those managed on site and other management locations (14.4% vs. 21.4%, n = 71 vs. 31, p = 0.053). Outcomes were benign in the majority of cases and there were no cases with Major (severe) outcomes or Death. CONCLUSION: Insulin dosing accidents can be routinely managed at home by PCs and have a low rate of hypoglycemia and adverse outcomes. This suggests that these cases can often be managed at home without referral with a potential benefit in no direct cost to the patient, convenience, and immediacy.

Determination of hypoglycaemia induced by insulin or its synthetic analogues post mortem.

The determination of human insulin or its synthetic analogues in post-mortem specimens represents a challenge for forensic toxicologists due to its proven instability in post-mortem blood. We present two cases of an insulin-induced hypoglycaemia. In the first case, ante-mortem material was available for the detection of an injection with human insulin. Human insulin was detected by immunopurification with magnetic beads and liquid chromatography-tandem mass spectrometry (LC-MS/MS) analyses at a concentration of 5180 µU/ml. The molar ratio human insulin:C-peptide was 111. The second case describes a suicide by self-injection of Insulin lispro and determination of the drug after pre-extraction with methanol and immunopurification by LC-MS/MS at the injection site, in vitreous humour and organs. Apart from the well-known matrices--femoral blood and urine--the specimen vitreous humour and the injection site promise the best possibilities for a proof of insulin at autopsy. In addition to insulin analyses, the parameters C-peptide, proinsulin, glucose, lactate, and sulfonylureas should be measured in case of suspected fatal hypoglycaemia.

Multi-modal brain imaging showing brain damage to the orbitofrontal cortex and left hemisphere, in a case of prolonged hypoglycemia-induced transient hemiplegia followed by persistent encephalopathy.

A 21-year-old left-handed male patient was admitted with a 19-h history of coma after substantial insulin injection for suicide attempt. Although the patient recovered from coma 3 days after injury, he experienced transient hemiplegia followed by permanent brain damage. Electroencephalogram (EEG), brain magnetic resonance imaging (MRI), and brain single-photon emission computed tomography (SPECT) identified the localization of this dysfunction, but consistency between clinical symptoms and brain images changed depending on the course of treatment. Transient hemiplegia corresponded to abnormal waveforms on EEG and decreased cerebral blood flow on SPECT, whereas persistent dysfunctions corresponded to abnormal brain regions on MRI and SPECT.