Serial blood lactate concentrations in systemically ill dogs

BACKGROUND: Lactate concentration often is quantified in systemically ill dogs and interpreted based on human data. To our knowledge, there are no published clinical studies evaluating serial lactate concentrations as a prognostic indicator in ill dogs. OBJECTIVES: Our objective was to perform a prospective study, using multivariate analysis, to determine whether serial lactate concentrations were associated with outcome in ill dogs requiring intravenous fluids. METHODS: Eighty sick dogs had lactate concentrations evaluated, using an analyzer that measures lactate in the plasma fraction of heparinized whole blood, at 0 hours and 6 hours after initiation of treatment. Severity of illness and outcome (survivor, nonsurvivor) were determined by reviewing the patient's record 2 weeks after admission. Lactate concentrations, age, body weight, gender, and severity of illness were evaluated using multivariate analysis to determine their effects on outcome. RESULTS: Dogs with lactate concentrations greater than the reference interval at 6 hours were 16 times (95% confidence interval = 2.32-112.71 times, P <.01) more likely not to survive compared to dogs with lactate concentrations within the reference interval. Lactate concentrations above the reference interval at 0 hours were not significantly related to outcome. However, hyperlactatemia that did not improve by > or = 50% within 6 hours was significantly associated with mortality (P = .024). CONCLUSION: Dogs with a lactate concentration higher than the reference interval at 6 hours were more likely not to survive. These results indicate an association between lactate concentration and outcome and emphasize the importance of serial lactate concentrations in evaluating prognosis.     

Lactate Kinetics in veterinary Critical Care: A Review

Elevation in blood lactate concentration, with or without accompanying metabolic acidosis, is a hallmark finding in patients with circulatory compromise, and is also consistently noted in other conditions affecting critically ill or injured individuals. Little is reported in a veterinary literature regarding lactate measurement in the emergency and critical care setting, despite impressive reports of the clinical usefulness of lactate measurement in people. The purpose of this article is to review lactate kinetics and the clinical utility of lactate measurement. Limitations to lactate evaluation will also be discussed.     

Relative adrenal insufficiency in critical illness

Objective: To review the effects of critical illness on hypothalamic–pituitary–adrenal (HPA) function in human and veterinary medicine. Data sources: Data from human and veterinary literature was reviewed. Human data synthesis: Relative adrenal insufficiency (RAI) appears to be common in critically ill human patients with sepsis or septic shock. Hypotension that is refractory to fluid therapy and requires vasopressors is the most common presentation of RAI in the human intensive care unit (ICU). Many investigators now advocate the use of a low‐dose adrenocorticotropin hormone stimulation test to diagnose RAI. It is important to evaluate for the presence of adrenal dysfunction, because current data suggest that treatment with ‘stress’ or low doses of glucocorticoids (200–300 mg hydrocortisone daily) may improve patient outcome in humans. Veterinary data synthesis: There is a paucity of controlled studies in the veterinary literature regarding the effects of critical illness on HPA function. The results of these studies are varied. However, research models of sepsis and hemorrhagic shock suggest the existence of RAI in animals. Prospective clinical studies are needed to further examine pituitary–adrenal response to severe illness in veterinary patients, and to determine if there are therapeutic options, including glucocorticoid administration, which will improve patient outcome in animals. Conclusions: RAI is well documented in critically ill human patients, yet little is known about adrenal dysfunction in veterinary critically ill patients. A small number of studies suggest that RAI may exist in certain subpopulations of veterinary patients. The syndrome of RAI could be considered as a differential diagnosis in seriously ill veterinary patients that fail to respond to appropriate therapy, especially when hypotension refractory to fluid and vasopressor therapy is encountered. This disorder may represent a previously unidentified syndrome in critically ill veterinary patients with important therapeutic implications.     

Lactate in veterinary critical care: pathophysiology and management

The measurement of blood lactate in people has proven to be a useful tool in the diagnosis, monitoring, and prognosis of a wide range of clinical syndromes. Its use in small animals is increasing, and several studies have been completed that demonstrate its potential role in critical care. This article summarizes the current state of knowledge regarding the physiology and pathophysiology of lactate production and lactic acidosis; current indications and the utility of measurement in a critical care setting are described; novel applications in the evaluation of cavitary effusions are highlighted; and a guide to the therapy of lactic acidosis is presented.     

Insulin, glucagon, and leptin in critically ill foals

Background: Endocrine dysregulation of hormones of energy metabolism is well documented in critically ill humans, but limited information exists in septic foals. The purpose of this study was to provide information on the hormonal response to energy metabolism in critically ill foals, focusing on insulin, glucagon, and leptin. Hypothesis: Concentrations of insulin, glucagon, leptin, and triglycerides will be higher, whereas glucose concentration will be lower in septic foals than in healthy and sick nonseptic foals. The magnitude of these differences will be associated with severity of disease and nonsurvival. Animals: Forty‐four septic, 62 sick nonseptic, and 19 healthy foals <7 days of age. Methods: In this prospective multicenter cross‐sectional study, blood samples were collected at admission. Foals with positive blood culture or sepsis score ≥12 were considered septic. Results: Septic foals had lower glucose and insulin and higher triglyceride and glucagon concentrations than did healthy foals. Glucagon concentrations were not different between septic foals that died (n = 14) or survived (n = 30). Higher insulin and lower leptin concentrations were associated with mortality. Quantitative insulin‐sensitivity check index was higher in septic foals. Conclusions and Clinical Importance: Energy metabolism and the endocrine response of related hormones in septic foals are characterized by hypoglycemia, hypertriglyceridemia, low insulin concentration, and high glucagon concentration. Leptin and insulin may have prognostic value for nonsurvival in septic foals. The hormonal response related to energy metabolism in critical illness differs between foals and humans.     

Regulation of lactate metabolism in the rumen

The regulation of lactic acid production, the regulation of lactate fermentation and the role of lactate as intermediate in the rumen metabolism was studied.The pH had a pronounced effect on all three processes and therefore buffer capacity of the rumen contents is also described.Starch gave much less rise to lactic acidosis than soluble sugars, as glucose and fructose. Most bacteria grow faster and therefore produce more lactic acid when amino acids and/or soluble proteins are present in the diet.Activity of LDH (lactate dehydrogenase) of mixed rumen microorganisms is regulated by the NADH/NAD (H) balance and the ATP concentration. About 60% of the LDH in mixed rumen microorganisms is fructose-1, 6-diphosphate independent. Megasphaera elsdenii ferments 60 to 80% of the lactate fermented in the rumen of dairy cattle.Lactate accumulates only when the glycolytic flux (hexose units fermented per unit time per microorganism) is high. During adaptation, the glycolytic flux is increased and lactate may accumulate. After adaptation to a certain diet, the number of microorganisms is changed and the glycolytic flux again is normal and lactate is only a minor intermediate in rumen metabolism.     

Nutritional requirements of the critically ill patient

The presence or development of malnutrition during critical illness has been unequivocally associated with increased morbidity and mortality in people. Recognition that malnutrition may similarly affect veterinary patients emphasizes the need to properly address the nutritional requirements of hospitalized dogs and cats. Because of a lack in veterinary studies evaluating the nutritional requirements of critically ill small animals, current recommendations for nutritional support of veterinary patients are based largely on sound clinical judgment and the best information available, including data from experimental animal models and human studies. This, however, should not discourage the veterinary practitioner from implementing nutritional support in critically ill patients. Similar to many supportive measures of critically ill patients, nutritional interventions can have a significant impact on patient morbidity and may even improve survival. The first step of nutritional support is to identify patients most likely to benefit from nutritional intervention. Careful assessment of the patient and appraisal of its nutritional needs provide the basis for a nutritional plan, which includes choosing the optimal route of nutritional support, determining the number of calories to provide, and determining the composition of the diet. Ultimately, the success of the nutritional management of critically ill dogs and cats will depend on close monitoring and frequent reassessment.     

Nosocomial infections and antimicrobial resistance in critical care medicine

Objective: To review the human and companion animal veterinary literature on nosocomial infections and antimicrobial drug resistance as they pertain to the critically ill patient. Data sources: Data from human and veterinary sources were reviewed using PubMed and CAB. Human data synthesis: There is a large amount of published data on nosocomially‐acquired bloodstream infections, pneumonia, urinary tract infections and surgical site infections, and strategies to minimize the frequency of these infections, in human medicine. Nosocomial infections caused by multi‐drug‐resistant (MDR) pathogens are a leading cause of increased patient morbidity and mortality, medical treatment costs, and prolonged hospital stay. Epidemiology and risk factor analyses have shown that the major risk factor for the development of antimicrobial resistance in critically ill human patients is heavy antibiotic usage. Veterinary data synthesis: There is a paucity of information on the development of antimicrobial drug resistance and nosocomially‐acquired infections in critically ill small animal veterinary patients. Mechanisms of antimicrobial drug resistance are universal, although the selection effects created by antibiotic usage may be less significant in veterinary patients. Future studies on the development of antimicrobial drug resistance in critically ill animals may benefit from research that has been conducted in humans. Conclusions: Antimicrobial use in critically ill patients selects for antimicrobial drug resistance and MDR nosocomial pathogens. The choice of antimicrobials should be prudent and based on regular surveillance studies and accurate microbiological diagnostics. Antimicrobial drug resistance is becoming an increasing problem in veterinary medicine, particularly in the critical care setting, and institution‐specific strategies should be developed to prevent the emergence of MDR infections. The collation of data from tertiary‐care veterinary hospitals may identify trends in antimicrobial drug resistance patterns in nosocomial pathogens and aid in formulating guidelines for antimicrobial use.     

Nutrition in critical illness.

Malnutrition associated with critical illness has been unequivocally associated with increased morbidity and mortality in humans. Because malnutrition may similarly affect veterinary patients, the nutritional requirements of hospitalized critically ill animals must be properly addressed. Proper nutritional support is increasingly being recognized as an important therapeutic intervention in the care of critically ill patients. The current focus of veterinary critical care nutrition, and the major focus of this article, is on carefully selecting the patients most likely to benefit from nutritional support, deciding when to intervene, and optimizing nutritional support to individual patients.     

Measurement of plasma colloid osmotic pressure in neonatal foals under intensive care: comparison of direct and indirect methods and the association of COP with selected clinical and clinicopathologic variables

Objectives: To describe and compare admission colloid osmotic pressure (COP) measurement using both direct and indirect methods in neonatal foals under intensive care, and to evaluate for associations between COP and clinical/clinicopathologic parameters. Design: Prospective study. Setting: Intensive care unit at a veterinary medical teaching hospital. Animals: Twenty‐six critically ill neonatal foals were studied. A control group consisted of 9 clinically healthy neonatal foals. Interventions: Clinicopathologic data were collected at the time of admission. COP was measured directly using a colloid osmometer. Indirect COP was calculated using equations by both Landis–Pappenheimer (L–P) and Thomas and Brown. Measurements and main results: Measured admission COP values were 17.1±4.3 and 17.7±2.4 mmHg in critically ill and control foals, respectively, and these values were not significantly different. Critically ill foals with blood lactate concentrations >3 mmol/L had lower COP values than those with lactate ≤3 mmol/L. There was close agreement between indirect COP values calculated using the L–P equation and direct COP values measured in control foals (mean error=0.0±1.3 mmHg; R²=0.87). However, indirect values were not as predictive of direct COP in critically ill foals (mean error=0.8±3.8 mmHg; R²=0.64). As COP values increased, the indirect method tended to overestimate COP, whereas at lower values it slightly underestimated COP. Conclusion: While the L–P equation was a close approximation of direct COP in healthy foals, direct measurements of oncotic pressure cannot be replaced for monitoring of critically ill foals. Critically ill foals with higher lactate concentrations had lower COP values, suggesting a possible relationship between COP and lactate.     

Review of hypocalcemia in septic patients

Objective: To review the occurrence and etiologies of hypocalcemia in septic human and veterinary patients. Data sources: A thorough search was conducted using CAB abstracts and MEDLINE and the keywords hypocalcemia, ionized calcium, sepsis, and procalcitonin (proCT). Human data synthesis: Ionized hypocalcemia (iHCa) is a common finding in septic human patients. The cause is unknown but is likely multifactorial. Low ionized calcium (iCa²⁺) concentrations coincide with increased severity of illness and increased mortality. Recent studies show that iHCa has a strong correlation with elevated calcitonin precursor concentrations. Veterinary data synthesis: There is a paucity of publications in the veterinary literature pertaining to iHCa in septic animals. Experimental models of sepsis indicate that iHCa exists in animals. iHCa has also been investigated in horses with enterocolitis and endotoxemia. Prospective studies are needed to determine the prevalence of iHCa among septic small animals, and to determine whether iHCa correlates with increased mortality and severity of disease. Indications for the treatment of iHCa in septic small animals also need to be investigated. Conclusions: iHCa is well documented in septic human patients, but little is known about iHCa in septic veterinary patients. Future veterinary studies should focus on documenting the presence of iHCa in septic patients and steps should be taken to determine the cause. proCT concentrations may show promise for predicting sepsis and mortality in critically ill veterinary patients.     

Correlation between anion gap, blood L lactate concentration and survival in horses

Blood L lactate concentration and anion gap were measured in 32 horses suspected of having metabolic acidosis. There was good linear correlation between these variables (r = 0.90791, P less than 0.0001) and both were good prognostic indicators. Anion gap was a good indicator of the presence but not the severity of L lactic acidosis and was a slightly better prognostic indicator. The ability to predict survival was not improved by the measurement of L lactate in addition to anion gap.     

LIVER METABOLISM DURING MALIGNANT HYPERTHERMIA IN THE PIETRAIN PIG

Liver function was systematically investigated in 7 malignant hyperthermia (MH) susceptible Pietrain pigs (mean weight 67 kg ± 7 kg SEM) to determine the contribution of hepatic metabolism to circulating substrates (Hall, Lucke, Lovell and Lister 1978). It was considered that the progressive lactic acidosis observed in MH may be a result, not only of impaired hepatic uptake of lactate but also production of lactate by the liver as is said to occur in Type II lactic acidosis (Cohen and Simpson 1975). These authors suggested that as the enzyme pyruvate decarboxylase is pH sensitive, and because it is rate limiting in the gluconeugenic pathway of lactate to glucose, under conditions of severe acidosis (pH 7.1) hepatic lactate uptake will be inhibited and there will be production of lactate by the liver. Pigs were prepared with hepatic vein, right ventricle and common carotid artery cannulae. Control measurements were made before inducing MH by ventilating with 1% halothane for 10 minutes together with intravenous injection of 1 mg suxamethonium chloride per kg body weight. Paired arterial and hepatic venous samples were collected at 10 minute intervals for the following estimations: pH, oxygen content, glucose, potassium, lactate, pyruvate, alanine, free fatty acids and glycerol. Hepatic blood flow was estimated by continuous infusion of Indocyanine green (Lucke and Hall 1978). All pigs developed MH with a rise in mean muscle temperature from 37.8°C to 41.5°C after 40 minutes. Mean hepatic blood flow decreased to 25% of control value but, because there was a concomitant increase in oxygen extraction by the liver, hepatic oxygen consumption did not change significantly. At 20 minutes after MH there was a 7-fold increase in glucose efflux from the liver with an arterial glucose concentration of 12.6 mmol/1. There was a massive efflux of 1.1 mmol K+/min early in the response showing that the characteristic hyperkalaemia is not only due to potassium loss from muscle but mainly hepatic in origin. The mean lactate uptake by the liver increased from the control 0.21 mmol/min to 1.19 mmol/min after 10 minutes MH. Even in the presence of gross acidosis (mean pH 6.75) and hepatic blood flow 25% of control, hepatic lactate uptake was still 3 times that recorded in the resting state. It is important to note, however, that although hepatic lactate uptake was increased under these conditions, it was still insufficient in the presence of gross muscle stimulation with a mean arterial lactate concentration of 19.3 mmol/l. It is concluded that the lactic acidosis in porcine MH is due to peripheral overproduction with some impairment of hepatic uptake. The gluconeugenic capacity of the liver was never completely inhibited despite the severity of the metabolic acidosis and hyperthermia and at no stage was there production of lactate by the liver.     

Hypocalcemia in a critically ill patient

Objective: To present a case of clinical hypocalcemia in a critically ill septic dog. Case summary: A 12‐year old, female spayed English sheepdog presented in septic shock 5 days following hemilaminectomy surgery. Streptococcus canis was cultured from the incision site. Seven days after surgery, muscle tremors were noted and a subsequent low serum ionized calcium level was measured and treated. Intensive monitoring, fluid therapy, and antibiotic treatment were continued because of the sepsis and hypocalcemia, but the dog was euthanized 2 weeks after surgery. New or unique information provided: Low serum ionized calcium levels are a common finding in critically ill human patients, especially in cases of sepsis, pancreatitis, and rhabdomyolysis. In veterinary patients, sepsis or streptococcal infections are not commonly thought of as a contributing factor for hypocalcemia. Potential mechanisms of low serum ionized calcium levels in critically ill patients include intracellular accumulation of calcium ions, altered sensitivity and function of the parathyroid gland, alterations in Vitamin D levels or activity, renal loss of calcium, and severe hypomagnesemia. Pro‐inflammatory cytokines and calcitonin have also been proposed to contribute to low ionized calcium in the critically ill. Many veterinarians rely on total calcium levels instead of serum ionized calcium levels to assess critical patients and may be missing the development of hypocalcemia. Serum ionized calcium levels are recommended over total calcium levels to evaluate critically ill veterinary patients.     

Retrospective Study: The association of blood lactate concentration with outcome in dogs with idiopathic immune‐mediated hemolytic anemia: 173 cases (2003–2006)

Objective – To determine the association of blood lactate with outcome and response to transfusion therapy in dogs with idiopathic immune‐mediated hemolytic anemia (IMHA). Design – Retrospective study. Setting – Urban veterinary small animal emergency hospital. Animals – One hundred and seventy‐three client‐owned dogs with IMHA. Interventions – None. Measurements and Main Results – Serial blood lactate concentration, therapeutic interventions, and outcome were recorded. Nonsurvivors were defined as those that died or were euthanized. One hundred and thirty‐three dogs (77%) survived, 35 (20%) were euthanized, and 5 (3%) died. One hundred forty‐five dogs (84%; 145/173) had a lactate concentration above the laboratory reference interval [0.46–2.31 mmol/L] on presentation. Blood lactate at presentation was higher in the nonsurvivors (median 4.8 mmol/L; 0.5–13.6) compared with survivors (median 2.9 mmol/L; 0.3–13.2) (P<0.01). All dogs presenting with hyperlactatemia that normalized (<2.0 mmol/L) within 6 hours of admission survived, whereas, 71% of dogs that had a persistent hyperlactatemia at 6 hours survived (P=0.034). Lactate was positively correlated with age, BUN, and alkaline phosphatase, and inversely correlated with PCV. Receiver operating curve analysis for lactate concentration at admission as a test for outcome had an area under the curve of 0.69 with an optimal lactate cutoff concentration of 4.4 mmol/L correctly predicting outcome 73% of the time (sensitivity 60%, specificity 77%). Conclusions – Lactate concentration at presentation was significantly higher in nonsurvivors than survivors. Lactate was significantly correlated with previously reported outcome variables but lactate concentration at admission, as a predictor for outcome was less than optimal. However, serial lactate concentration measurements may be more predictive as patients with persistent hyperlactatemia 6 hours after admission were less likely to survive. Prospective studies evaluating serial lactate concentration while controlling for other variables may provide further insight into lactate measurement as a prognostic indicator in animals with IMHA.     

Arterial lactate concentration, hospital survival, sepsis and SIRS in critically ill neonatal foals

REASONS FOR PERFORMING STUDY: Blood lactate concentration has been shown to be a useful clinical indicator in human patients, but has not been formally investigated in critically ill foals. OBJECTIVE: To investigate the association of blood lactate with hospital survival, markers of cardiovascular status, metabolic acid base status, sepsis and systemic inflammatory response syndrome (SIRS). METHODS: A database containing clinical, haematological, plasma biochemical and hospital outcome data on neonatal foals referred to an intensive care unit in 2000-2001 was analysed. Seventy-two foals for which arterial lactate was measured at admission were included in the study. RESULTS: Sixty-one foals had an admission lactate concentration > 2.5 mmol/l. Admission lactate was statistically associated with hospital survival, mean arterial pressure, blood creatinine concentration, bacteraemia, anion gap, lactate concentration at 18-36 h after admission and evidence of SIRS, but not with packed cell volume or heart rate. Lactate at 18-36 h was also associated with survival and evidence of SIRS. Anion gap, base excess, base excess due to unidentified anions (BEua), simplified strong ion gap or bicarbonate correctly classified foals for presence of hyperlactaemia (> 5 mmol/l) in < or = 80% of animals. CONCLUSIONS: Admission blood lactate gives important prognostic information. Lactate should be measured rather than assumed from the anion gap, base excess, BEua, simplified strong ion gap or bicarbonate. POTENTIAL RELEVANCE: Blood lactate concentrations at admission are clinically relevant in neonatal foals and warrant further investigation. This should include the clinical value of measuring changes in lactate in response to treatment.     

Optimal endpoints of resuscitation and early goal-directed therapy

Objective: To review the available endpoints of shock resuscitation, including traditional perfusion parameters, oxygen‐transport variables, lactate, base deficit (BD), venous oxygen saturation, and gastric mucosal pH, and to discuss the currently accepted methods of assessing successful reversal of oxygen (O₂) debt in shock patients. Human‐based studies: Early goal‐directed therapy has unequivocally been shown to positively affect outcome in human patients experiencing cardiovascular shock. However, specific endpoints of resuscitation to target in critically ill patients remain controversial. Reliance on traditional endpoints of resuscitation (heart rate [HR], blood pressure [BP]) appears insufficient in detection of ongoing tissue hypoxia in shock states. A multitude of publications exist suggesting that indirect indices of global (lactate, base deficit, mixed/central venous oxygen saturation), regional (gastric intramucosal pH [pH_i]) and cellular (transcutaneous oxygen) oxygenation are more successful in outcome prediction and in assessing adequacy of resuscitative efforts in this patient population. Veterinary‐based studies: While there are several large studies evaluating endpoints of resuscitation in experimental canine shock models, this author was unable to find similar research pertaining to small animal veterinary patients. The few articles in which blood lactate is evaluated for prognostic purposes in canine patients are included in this review. Data sources: Veterinary and human literature review. Conclusions: Optimization of early resuscitative efforts has proven to have a survival benefit in human shock patients, and major strides have been made in determining which endpoints of resuscitation to target in this patient population. Similar clinical trials designed to evaluate indices of ongoing global and regional tissue hypoxia in small animal veterinary shock patients are warranted.     

Preliminary Investigation of the Area Under the l‐Lactate Concentration–Time Curve (LACAREA) in Critically Ill Equine Neonates

Background

A variety of measures of l‐lactate concentration ([LAC]) in the blood of critically ill neonatal foals have shown utility as prognostic indicators. These measures, evaluating either the severity of hyperlactatemia or the duration of exposure to hyperlactatemia, perform fairly well and have correctly classified 75–80% of foals examined in several studies. The area under the l‐lactate concentration versus time curve (LAC _Area) encompasses both severity and duration of hyperlactatemia and should improve correct classification of patient survival.

Hypothesis/Objectives

LAC _Area is larger in nonsurviving critically ill neonatal foals.

Animals

Forty‐nine foals admitted for critical illness to 1 of 4 referral hospitals.

Methods

Whole blood was obtained at admission and 6, 12, 18, and 24 hours after admission for measurement of l‐lactate using a handheld lactate meter. LAC _Area was calculated for: admission–6, 6–12, 12–18, 18–24 hours, and admission–24 hours using the trapezoidal method and summing the 6‐hours interval areas to determine total 24 hours area. Differences between survivors and nonsurvivors were determined using robust regression and Kruskal–Wallis testing, P < .05.

Results

LAC _Area was significantly larger in nonsurviving foals (n = 9) than in surviving foals (n = 40) at all time periods examined.

Conclusions and Clinical Importance

Differences in LAC _Area between surviving and nonsurviving critically ill neonatal foals are large and support further investigation of this method as an improved biomarker for survival in critically ill neonatal foals is indicated.     

Acute pancreatitis in dogs

Objective: To summarize current information regarding severity assessment, diagnostic imaging, and treatment of human and canine acute pancreatitis (AP). Human‐based studies: In humans, scoring systems, advanced imaging methods, and serum markers are used to assess the severity of disease, which allows for optimization of patient management. The extent of pancreatic necrosis and the presence of infected pancreatic necrosis are the most important factors determining the development of multiple organ failure (MOF) and subsequent mortality. Considerable research efforts have focused on the development of inexpensive, easy, and reliable laboratory markers to assess disease severity as early as possible in the course of the disease. The use of prophylactic antibiotics, enteral nutrition, and surgery have been shown to be beneficial in certain patient populations. Veterinary‐based studies: The majority of what is currently known about naturally occurring canine AP has been derived from retrospective evaluations. The identification and development of inexpensive and reliable detection kits of key laboratory markers in dogs with AP could dramatically improve our ability to prognosticate and identify patient populations likely to benefit from treatment interventions. Treatment remains largely supportive and future studies evaluating the efficacy of surgery, nutritional support and other treatment modalities are warranted. Data sources: Current human and veterinary literature. Conclusions: Pancreatitis can lead to a life‐threatening severe systemic inflammatory condition, resulting in MOF and death in both humans and dogs. Given the similarities in the pathophysiology of AP in both humans and dogs, novel concepts used to assess severity and treat people with AP may be applicable to dogs.