Using measured cannabidiol and tetrahydrocannabinol metabolites in urine to differentiate marijuana use from consumption of commercial cannabidiol products.

CONTEXT: Detecting marijuana use is a component of most urine drug screens targeting a single Δ9-tetrahydrocannabinol metabolite. Recently, the non-intoxicating cannabinoid, cannabidiol (CBD), has gained popular acceptance for a myriad of reasons. Commercially available CBD products sold without purity regulations have become ubiquitous. Many products contain trace tetrahydrocannabinol. Long-term or high dose use of CBD products can result in tetrahydrocannabinol exposures, potentially producing a positive marijuana drug test. These results are not false positives since marijuana biomarkers are present, but inaccurately identify donors as marijuana users. Addressing this conundrum, we developed an assay discriminating marijuana use from the use of CBD contaminated with tetrahydrocannabinol. METHODS: Following the synthesis of a primary CBD metabolite, a LC-MS/MS assay was developed measuring the urinary metabolites tetrahydrocannabinol, 11-nor-carboxy-Δ9-tetrahydrocannabinol, CBD, and 7-carboxy-cannabidiol. The assay was utilized on 425 patients claiming CBD use, and sixteen samples from trusted users of commercial CBD products. RESULTS AND DISCUSSION: Clear data clusters enabled metabolic cut-points assignments. Forty-three percent of samples contained CBD metabolites in ten-fold excess to tetrahydrocannabinol metabolites which was then used as a set point to classify donors as CBD users. An excess of tetrahydrocannabinol metabolites classify donors as marijuana users. Additionally, urine samples were procured from donors personally known to use commercial CBD ad libitum, yet abstain from tetrahydrocannabinol. Results from trusted users substantiated the use of the resulting metabolic ratios despite 11-carboxy-tetrahydrocannabinol measured in 75% of these samples. CONCLUSION: A method has been developed and utilized to distinguish marijuana use from tetrahydrocannabinol exposure from contaminated CBD use.

A randomized trial comparing physostigmine vs lorazepam for treatment of antimuscarinic (anticholinergic) toxidrome.

BACKGROUND: Toxicity from antimuscarinic agents precipitates a constellation of signs and symptoms; two of the most significant are agitation and delirium. Benzodiazepines are commonly used for treatment; physostigmine is also effective but is underutilized due to concerns for safety and short duration of action. The objective of this study was to compare lorazepam to physostigmine for the treatment of antimuscarinic delirium and agitation. METHODS: This was a blinded, randomized clinical trial in patients presenting for antimuscarinic toxidrome. Inclusion criteria were: ≥10-<18 years old, at least one central and two peripheral antimuscarinic symptoms, delirium and moderate agitation. Subjects were randomized to either (1) lorazepam bolus (0.05 mg/kg) followed by a 4-h normal saline infusion, or (2) physostigmine 0.02 mg/kg bolus followed by a 4-h physostigmine infusion (0.02 mg/kg/h). Primary outcomes were the control of delirium and agitation after bolus and during the infusion. RESULTS: Ten (53%) subjects were enrolled in the lorazepam arm, 9 (47%) in the physostigmine arm. Diphenhydramine was the most common agent ingested (16, 84%). Fewer patients receiving physostigmine had delirium after the initial bolus (44% vs 100%, p = 0.01) and at the 4th hour of infusion (22% vs 100%, p < 0.001) compared to patients who received lorazepam. There was a significant decrease in agitation scores in the physostigmine arm compared to the lorazepam arm after the initial bolus (89% vs 30%, p = 0.02), but no difference at the 4th hour of infusion (p > 0.99). There were no seizures, bradycardia, bronchorrhea, bronchospasm, intubation, or cardiac dysrhythmias. CONCLUSION: Physostigmine was superior to lorazepam in controlling antimuscarinic delirium and agitation after bolus dosing, and control of delirium after a 4-h infusion. There were no serious adverse events in either treatment arm. Physostigmine bolus and infusion should be considered in adolescent patients with significant delirium and agitation from antimuscarinic agents.

Reduced urinary opioid levels from pain management patients associated with marijuana use.

Aim: Marijuana use has been postulated to modulate opioid use, dependence and withdrawal. Broad target drug testing results provide a unique perspective to identify any potential interaction between marijuana use and opioid use. Materials & methods: Using a dataset of approximately 800,000 urine drug test results collected from pain management patients of a time from of multiple years, creatinine corrected opioid levels were evaluated to determine if the presence of the primary marijuana marker 11-nor-carboxy-tetrahydrocannabinol (THC-COOH) was associated with statistical differences in excreted opioid concentrations. Results & conclusion: For each of the opioids investigated (codeine, morphine, hydrocodone, hydromorphone, oxycodone, oxymorphone, fentanyl and buprenorphine), marijuana use was associated with statistically significant lower urinary opiate levels than in samples without indicators of marijuana use.

Analysis of Synthetic Cannabinoid Metabolites by Liquid Chromatography-Tandem Mass Spectrometry.

The analysis of synthetic cannabinoid compounds in a urine sample is currently one of the more complex tasks facing toxicologists. The list of prevalent compounds in circulation at any given time is constantly in flux, changing at a rapid rate to avoid legal control and to a lesser extent to avoid detection. Even with knowledge of the chemical entities, their detection in urine is complicated by the fact that they are present exclusively as both phase I metabolites and phase II conjugates. With proper knowledge of the correct analytical targets, relatively simple procedures are capable of extracting and analyzing synthetic cannabinoids. Following enzymatic hydrolysis, compounds can be extracted through liquid partitioning procedures, and the extracts are analyzed via LC-MS/MS.

Salt-Assisted Liquid-Liquid Extraction of Meconium for Analysis of Cocaine and Amphetamines by Liquid Chromatography-Tandem Mass Spectrometry.

Meconium, the first stool of a newborn, can be analyzed to identify prenatal exposure to drugs of abuse. Meconium accumulates in a fetus during the second and third trimesters of pregnancy providing a wide window of exposure. Identification of in utero drug exposure is essential for the diagnosis and treatment of infants for dependency/withdrawal caused from the exposure. However, testing of meconium samples is often cumbersome and time-consuming. Unlike liquid samples, meconium is a viscous, semisolid, tar-like substance that needs to be individually weighed prior to extraction. Additionally, the meconium matrix is not homogeneous and not easily mixed or extracted. A method for analyzing cocaine and metabolites as well as amphetamines in meconium utilizing ceramic homogenizers prior to salt-assisted liquid-liquid extraction and liquid chromatography tandem-mass spectrometry (LC-MS/MS) is presented.

The Fentanyl Epidemic and Evolution of Fentanyl Analogs in the United States and the European Union.

BACKGROUND: Since 2013, an unprecedented surge in fentanyl overdose deaths has been caused by heroin laced with illicitly produced fentanyl and/or fentanyl analogs (FAs) sold as heroin. The US Drug Enforcement Agency's National Forensic Laboratory Information System reported a >300% increase in fentanyl encounters from 4697 in 2014 to 14440 in 2015. In 2015, the CDC reported 9580 deaths caused by synthetic opioids, primarily fentanyl, a 72% increase from 2014. The European Monitoring Centre for Drugs and Drug Addiction has also encountered several new FAs in the heroin supply. Counterfeit pharmaceuticals containing mixtures of fentanyl and FAs continue to be a poorly recognized worldwide problem despite the WHO classifying several FAs as a serious threat to public health. CONTENT: This review covers the epidemiology of fentanyl abuse and discusses the clinical practice implications of widespread fentanyl abuse. It includes a historical perspective on the illicit FAs that have appeared in the US and European Union and reviews the methods available to identify FAs and emerging technologies useful for identifying previously undescribed analogs. A compilation of structural and mass spectral data on FAs reported thus far is provided. SUMMARY: Fentanyl and FAs have evolved into a global public health threat. It is important to understand the analytical, clinical, and regulatory efforts underway to assist communities affected by the current fentanyl epidemic.

Anodyne by Design; Measuring the Prevalence of Esoteric Designer Opioids in Pain Management Patients.

The recent increase in illicit opioids sold on the black market, cut into heroin and masqueraded as prescription pills prompts a significant public health concern. Most designer opioids possess unknown potencies and unknown pharmacokinetics and their unregulated, variable dosages lead to rashes of overdoses. Additionally, many of the designer opioids, especially the fentanyl analogs are significantly more potent than heroin. High-profile cases involving overdoses of U-47700 and carfentanil have been reported in the media; however, the true prevalence of these and other designer opioids is unknown. Independent LC-MS-MS screen and confirmation methods have been developed and validated to identify and quantify fentanyl, and 18 designer opioids and their metabolites; methods were then exercised on urine specimens from contract pain management clients. Assuming patients in a pain management program may have a higher probability to seek out self-medication, samples from pain management patients were investigated for designer opioids. Similarly, pain management patients identified as using heroin may be more likely to experiment with or be accidentally exposed to designer opioids, specimens screening positive for the heroin metabolite 6-acetylmorphine were specifically chosen for designer opioid screening. Within this small group of pain management and heroin-positive samples, nine designer opioids were detected at a total prevalence of 25%. When screening random pain management samples not positive for heroin, a considerably lower percentage of samples (<1%) were identified as positive for designer opioids. Furanyl fentanyl, fluorobutyryl fentanyl and acetylfentanyl were the most prevalent designer opioids detected in both test groups.

Identification of Unique Metabolites of the Designer Opioid Furanyl Fentanyl.

The illicit drug market has seen an increase in designer opioids, including fentanyl and methadone analogs, and other structurally unrelated opioid agonists. The designer opioid, furanyl fentanyl, is one of many fentanyl analogs clandestinely synthesized for recreational use and contributing to the fentanyl and opioid crisis. A method has been developed and validated for the analysis of furanyl fentanyl and furanyl norfentanyl in urine specimens from pain management programs. Approximately 10% of samples from a set of 500 presumptive heroin-positive urine specimens were found to contain furanyl fentanyl, with an average concentration of 33.8 ng/mL, and ranging from 0.26 to 390 ng/mL. Little to no furanyl norfentanyl was observed; therefore, the furanyl fentanyl specimens were further analyzed by untargeted high-resolution mass spectrometry to identify other metabolites. Multiple metabolites, including a dihydrodiol metabolite, 4-anilino-N-phenethyl-piperidine (4-ANPP) and a sulfate metabolite were identified. The aim of the presented study was to identify the major metabolite(s) of furanyl fentanyl and estimate their concentrations for the purpose of toxicological monitoring.

Profiting from Probability; Combining Low and High Probability Isotopes as a Tool Extending the Dynamic Range of an Assay Measuring Amphetamine and Methamphetamine in Urine.

A wide range of concentrations are frequently observed when measuring drugs of abuse in urine toxicology samples; this is especially true for amphetamine and methamphetamine. Routine liquid chromatography-tandem mass spectrometry confirmatory methods commonly anchored at a 50 ng/mL lower limit of quantitation can span approximately a 100-fold concentration range before regions of non-linearity are reached deteriorating accurate quantitation and qualitative assessments. In our experience, approximately a quarter of amphetamine and methamphetamine positive samples are above a 5,000 ng/mL upper limit of quantitation and thus require reanalysis with dilution for accurate quantitative and acceptable qualitative results. We present here the development of an analytical method capable of accurately quantifying samples with concentrations spanning several orders of magnitude without the need for sample dilution and reanalysis. For each analyte the major isotopes were monitored for analysis through the lower concentration ranges (50-5,000 ng/mL), and the naturally occurring, low probability 13C2 isotopes were monitored for the analysis of the high concentration samples (5,000-100,000 ng/mL amphetamine and 5,000-200,000 ng/mL methamphetamine). The method simultaneously monitors transitions for the molecules containing only 12C and 13C2 isotopologues eliminating the need for re-extraction and reanalysis of high concentration samples.

Catching Fakes: New Markers of Urine Sample Validity and Invalidity.

Urine drug testing is common for workplace drug testing, prescription management, emergency medicine and the criminal justice system. Unsurprisingly, with the significant consequences based upon the results of urine drug testing, a donor in need of concealing the contents of their sample is highly motivated to cheat the process. Procedures and safeguards ensuring sample validity are well known, and include measuring sample temperature at the time of collection, and laboratory measurements of creatinine, specific gravity and pH. Synthetic urine samples are available and are designed to deceive all aspects of urine drug testing, including validity testing. These samples are sophisticated enough to contain biological levels of creatinine, and are at a physiological pH and specific gravity. The goal of our research was to develop new procedures designed to distinguish authentic samples from masquerading synthetic samples. We aimed to identify substances in commercial synthetic urines not expected to be present in a biological sample distinguishing fake specimens. Additionally, we aimed to identify and employ endogenous compounds in addition to creatinine for identifying biological samples. We successfully identified two compounds present in synthetic urines that are not present in biological samples and use them as markers of invalidity. Four new endogenous markers for validity were successfully evaluated. Validity assessment was further aided by monitoring metabolites of nicotine and caffeine. When the method was applied to patient samples, 2% of samples were identified as inconsistent with natural urine samples, even though they met the current acceptance criteria for creatinine, pH and specific gravity.

A case of U-47700 overdose with laboratory confirmation and metabolite identification.

CONTEXT: The opioid epidemic has included use of traditional drugs and recently newer synthetics. It is critically important to recognize and identify these new drugs both clinically and through appropriately designed toxicology testing. There is little available information on a synthetic gaining popularity, U-47700. CASE DETAILS: A 23-year-old female presented after using "U4" by nasal insufflation and injection. She was cyanotic with respiratory depression and responded to naloxone in the field. She was found to have non cardiogenic pulmonary edema and hemoptysis which improved with BiPAP. Urine and serum samples were analyzed using mass spectrometry, confirming 3,4-dichloro-N-[(1R,2R)-2-(dimethylamino)cyclohexyl]-N-methylbenzamide or U-47700. The sample was further analyzed elucidating metabolism specifics. Drug and metabolite concentrations were subsequently measured in both serum and urine. The parent compound of U-47700 was detected at 394 ng/mL and 228 ng/mL in serum and urine, respectively. Metabolites detected in appreciable amounts included the desmethyl (1964 ng/mL in urine), bisdesmethyl (618 ng/mL), desmethyl hydroxy (447 ng/mL), and bisdesmethyl hydroxy forms (247 ng/mL) of U-47700. DISCUSSION: U-47700 is a potent µ-opioid receptor agonist and has recently been used recreationally, contributing to hospitalizations and likely deaths in the community. This is a case report describing an exposure to U-47700 with subsequent laboratory analysis. Based upon this one case, parent U-47700 appear to be an appropriate marker of use in a serum sample. However, demethylated metabolites appear dominant as urinary markers of U-47700 use.

2-(4-Iodo-2,5-dimethoxyphenyl)-N-[(2-methoxyphenyl)methyl]ethanamine (25I-NBOMe): clinical case with unique confirmatory testing.

INTRODUCTION: 2C designer drugs have been in use since the 1970s, but new drugs continue to develop from substitutions to the base phenethylamine structure. This creates new clinical profiles and difficulty with laboratory confirmation. 2-(4-Iodo-2,5-dimethoxyphenyl)-N-[(2-methoxyphenyl)methyl]ethanamine (25I-NBOMe) is a relatively new 2C drug that is more potent than structural 2C analogs; exposure reports are rare. Testing for 2C drugs is developing; specific testing for new analogs such as 25I-NBOMe is a challenge. These drugs do not reliably trigger a positive result on rapid drug immunoassays. Additionally, most facilities with confirmatory testing capabilities will not identify 25I-NBOMe; methods for detecting 25I-NBOMe in biological samples have not been clearly described nor have optimal metabolic targets for detecting 25I-NBOMe ingestion. CASE REPORT: An 18-year-old female presented following use of 25I-NBOMe. She had an isolated brief seizure, tachycardia, hypertension, agitation, and confusion. She improved with intravenously administered fluids and benzodiazepines and was discharged 7 h postingestion. Urine was analyzed using quantitative LC-MS/MS methodology for 25I-NBOMe, 2-(4-chloro-2,5-dimethoxyphenyl)-N-[(2-methoxyphenyl)-methyl]ethanamine (25C-NBOMe), and 2-(2,5-dimethoxyphenyl)-N-(2-methoxybenzyl)ethanamine (25H-NBOMe). 25I-NBOMe was found at a concentration of 7.5 ng/mL, and 25H-NBOMe was detected as well. Additional testing was pursued to characterize the metabolism of 25I-NBOMe; the sample was reanalyzed with UPLC-time-of-flight mass spectrometry to identify excreted metabolites. The sample was additionally analyzed for the presence of 2,5-dimethoxy-4-iodophenethylamine (2C-I), 4-bromo-2,5-dimethoxyphenethylamine (2C-B), and 1-(2,5-dimethoxy-4-ethylphenyl)-2-aminoethane (2C-E). DISCUSSION: This is a report of a patient presenting following exposure to 25I-NBOMe, a dangerous member of the evolving 2C drug class. The exposure was confirmed in a unique manner that could prove helpful in guiding further patient analysis and laboratory studies.

"Retention projection" enables reliable use of shared gas chromatographic retention data across laboratories, instruments, and methods.

Gas chromatography/mass spectrometry (GC/MS) is a primary tool used to identify compounds in complex samples. Both mass spectra and GC retention times are matched to those of standards; however, it is often impractical to have standards on hand for every compound of interest, so we must rely on shared databases of MS data and GC retention information. Unfortunately, retention databases (e.g., linear retention index libraries) are experimentally restrictive, notoriously unreliable, and strongly instrument dependent, relegating GC retention information to a minor, often negligible role in compound identification despite its potential power. A new methodology called "retention projection" has great potential to overcome the limitations of shared chromatographic databases. In this work, we tested the reliability of the methodology in five independent laboratories. We found that, even when each lab ran nominally the same method, the methodology was 3-fold more accurate than retention indexing because it properly accounted for unintentional differences between the GC/MS systems. When the laboratories used different methods of their own choosing, retention projections were 4- to 165-fold more accurate. More importantly, the distribution of error in the retention projections was predictable across different methods and laboratories, thus enabling automatic calculation of retention time tolerance windows. Tolerance windows at 99% confidence were generally narrower than those widely used even when physical standards are on hand to measure their retention. With its high accuracy and reliability, the new retention projection methodology makes GC retention a reliable, precise tool for compound identification, even when standards are not available to the user.

Biomarker evidence of tobacco smoke exposure in children participating in lead screening.

OBJECTIVES: We assessed tobacco smoke exposure (TSE), defined according to detection of cotinine, in dried blood spots collected from children for lead screening. METHODS: Dried blood spots collected from a national sample of 1541 Black and White children and submitted to a commercial laboratory for lead analysis were analyzed for cotinine. We used an anonymous administrative data set including information on children's characteristics to conduct univariate and multivariate analyses. RESULTS: Cotinine was detected in 61% of dried blood spots; 17% of samples had cotinine levels above 3 nanograms per gram. Median cotinine levels were significantly higher among Black than White children (0.66 ng/g vs 0.30 ng/g) and among Medicaid recipients (0.94 ng/g vs < 0.3 ng/g). In multivariate analyses, significant increases in cotinine levels were associated with Black (vs White) race, older age, Medicaid coverage, higher state smoking rate, and higher average winter temperature. Detectable cotinine levels were significantly associated with higher lead levels. CONCLUSIONS: TSE is highly prevalent among children undergoing lead screening, and exposure levels are greater among Black children and children on Medicaid. TSE may contribute to lead exposure. Concurrent lead screening and biological screening for TSE may be a feasible approach to increasing childhood TSE detection.

Analysis of mitragynine and metabolites in human urine for detecting the use of the psychoactive plant kratom.

The leaves of the South Asian plant kratom are described as having stimulating effects at low doses, and opiate-like analgesic and euphoric effects at high doses. A long history of use and abuse has led to the classification of kratom as a controlled substance in its native Thailand and other South Asian countries. However, kratom is not controlled in the United States, and the ready availability of kratom has led to its emergence as an herbal drug of abuse. With the growing popularity of kratom, efficient procedures are needed to detect kratom use. In the current study, both ultra-high-performance liquid chromatography and high-performance liquid chromatography-tandem mass spectrometry methods have been developed and validated for monitoring the major alkaloids and metabolites found in urine following kratom use. The primary unique alkaloid mitragynine is quantified in human urine from 1.00-500.00 ng/mL using mitraphylline as an internal standard. In addition, two metabolites (5-desmethylmitragynine and 17-desmethyldihydromitragynine) and the related active, alkaloid 7-hydroxy-mitragynine, are simultaneously qualitatively monitored. The presence of analytes are confirmed by an information-dependent acquisition-enhanced product ion procedure generating full fragmentation data used to positively identify detected analytes. The validated method has been utilized for clinical and forensic analyses of urine for the detection of kratom use.

Analysis of selected anticonvulsants by high performance liquid chromatography-tandem mass spectrometry.

A method for the analysis of the basic antiepileptic compounds felbamate, lamotrigine, carbamazepine, carbamazepine-10,11-epoxide, gabapentin, pregabalin, levetiracetam, and oxcarbazepine monohydroxy derivative (oxcarb MHD) in human plasma is described. This protocol incorporates a simplified sample preparation step followed by quantitative high performance chromatography-tandem mass spectrometry detection of commonly prescribed and monitored anticonvulsant drugs. Since polytherapy is common in epilepsy patients, use of a multiconstituent assay can improve laboratory efficiency and reduce required analytical time.

Quantitation of DNA adducts by stable isotope dilution mass spectrometry.

Exposure to endogenous and exogenous chemicals can lead to the formation of structurally modified DNA bases (DNA adducts). If not repaired, these nucleobase lesions can cause polymerase errors during DNA replication, leading to heritable mutations and potentially contributing to the development of cancer. Because of their critical role in cancer initiation, DNA adducts represent mechanism-based biomarkers of carcinogen exposure, and their quantitation is particularly useful for cancer risk assessment. DNA adducts are also valuable in mechanistic studies linking tumorigenic effects of environmental and industrial carcinogens to specific electrophilic species generated from their metabolism. While multiple experimental methodologies have been developed for DNA adduct analysis in biological samples, including immunoassay, HPLC, and ³²P-postlabeling, isotope dilution high performance liquid chromatography-electrospray ionization-tandem mass spectrometry (HPLC-ESI-MS/MS) generally has superior selectivity, sensitivity, accuracy, and reproducibility. As typical DNA adduct concentrations in biological samples are between 0.01-10 adducts per 108 normal nucleotides, ultrasensitive HPLC-ESI-MS/MS methodologies are required for their analysis. Recent developments in analytical separations and biological mass spectrometry, especially nanoflow HPLC, nanospray ionization MS, chip-MS, and high resolution MS, have pushed the limits of analytical HPLC-ESI-MS/MS methodologies for DNA adducts, allowing researchers to accurately measure their concentrations in biological samples from patients treated with DNA alkylating drugs and in populations exposed to carcinogens from urban air, drinking water, cooked food, alcohol, and cigarette smoke.

Analysis of total and transferrin-bound iron in human serum for pharmacokinetic studies of iron-sucrose formulations.

BACKGROUND: Patients with iron-deficiency anemia benefit from intravenous iron therapies. Development of these pharmaceutical agents requires pharmacokinetic studies monitoring levels of both the administered agent and transferrin-bound iron (TBI). Successful pharmacokinetic methods must discriminate iron species. RESULTS: Routine colorimetric procedures were used to reliably measure total iron and TBI following iron-sucrose administration. Iron was liberated from iron-sucrose allowing the determination of all circulating iron. Solid-phase sample processing allowed the measurement of TBI. Circulating iron-sucrose could then be calculated as the difference between total iron and TBI. CONCLUSION: A reproducible and robust spectrophotometric method was developed and validated for measuring total iron and TBI in human serum following iron-sucrose therapy.

Pathway for the management of survivors of out-of-hospital cardiac arrest.

The estimated number of out-of-hospital care arrest cases is about 300,000 per year in the United States. Two landmark studies published in 2002 demonstrated that the use of therapeutic hypothermia after cardiac arrest decreased mortality and improved neurologic outcome. Based on these studies, the International Liaison Committee on Resuscitation and the American Heart Association recommended the use of therapeutic hypothermia after cardiac arrest. Therapeutic hypothermia is defined as a controlled lowering of core body temperature to 32 degrees C to 34 degrees C. This temperature goal represents the optimal balance between clinical effect and cardiovascular toxicity. Therapeutic hypothermia does require resources to implement-including device, close nursing care, and monitoring. It is important to select patients who have potential for benefit from this technique which is a limited resource and carries potential complications. A collaborative team approach involving physicians and nurses is critical for successful development and implementation of this kind of a protocol. In 2004, the "Advanced Cardiac Admission Program" was launched at the St. Luke's Roosevelt Hospital Center of Columbia University in New York. The program consists of a series of projects, which have been developed to bridge the gap between published guidelines and implementation during "real world" patient care. In this article, we are reporting our latest project for the comprehensive management of survivors of out-of-hospital cardiac arrest. The pathway is divided into 3 steps: Step I, From the field through the emergency department into the cardiac catherization laboratory and to the critical care unit; Step II, Induced invasive hypothermia protocol in the critical care unit (this step is divided into 3 phases: 1, invasive cooling for the first 24 hours; 2, rewarming; 3, maintenance); Step III, Management post the rewarming phase including the recommendation for out-of-hospital therapy and the ethical decision to define goal of care. We hope that this novel pathway will bridge the gap between the complex guidelines and the actual clinical practice and will improve the survival and neurologic condition of patients suffering cardiac arrest.