Hostname: page-component-586b7cd67f-rcrh6 Total loading time: 0 Render date: 2024-11-24T09:07:21.308Z Has data issue: false hasContentIssue false

The Effectiveness of Prehospital Subcutaneous Continuous Lactate Monitoring in Adult Trauma: A Systematic Review

Published online by Cambridge University Press:  04 December 2023

Jamie W. Scriven*
Affiliation:
School of Medicine, Cardiff University, Cardiff, Wales West Midlands Central Accident, Resuscitation & Emergency Team, Birmingham, England
Emir Battaloglu
Affiliation:
West Midlands Central Accident, Resuscitation & Emergency Team, Birmingham, England University Hospitals Birmingham NHS Foundation Trust, Birmingham, England
*
Correspondence: Dr. Jamie W. Scriven School of Medicine UHW Main Building Heath Park, Cardiff, CF14 4XN E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Introduction:

Existing diagnostics for polytrauma patients continue to rely on non-invasive monitoring techniques with limited sensitivity and specificity for critically unwell patients. Lactate is a known diagnostic and prognostic marker used in infection and trauma and has been associated with mortality, need for surgery, and organ dysfunction. Point-of-care (POC) testing allows for the periodic assessment of lactate levels; however, there is an associated expense and equipment burden associated with repeated sampling, with limited feasibility in prehospital care. Subcutaneous lactate monitoring has the potential to provide a dynamic assessment of physiological lactate levels and utilize these trends to guide management and response to given treatments.

Study Objective:

The aim of this study was to appraise the current literature on dynamic subcutaneous continuous lactate monitoring (SCLM) in adult trauma patients and its use in lactate-guided therapy in the prehospital environment.

Methods:

The systematic review was conducted in accordance with the PRISMA guidelines and registered with PROSPERO. Searched databases included PubMed, EMBASE via Ovid SP, Cochrane Library, and Web of Science. Databases were searched from inception to March 29, 2022. Relevant manuscripts were further scrutinized for reference citations to interrogate the fullness of the adjacent literature.

Results:

Searches returned 600 studies, including 551 unique manuscripts. Following title and abstract screening, 14 manuscripts met the threshold for full-text sourcing. Subsequent to the scrutiny of all 14 manuscripts, none fully met the specified eligibility criteria. Following careful examination, no article was found to cover the exact area of scientific inquiry due to disparity in technological or environmental characteristics.

Conclusion:

Little is known about the utility of dynamic subcutaneous lactate monitoring, and this review highlights a clear gap in current literature. Novel subcutaneous lactate monitors are in development, and the literature describing the prototype experimentation has been summarized. These studies demonstrate device accuracy, which shows a close correlation with venous lactate while providing dynamic readings without significant lag times. Their availability and cost remain barriers to implementation at present. This represents a clear target for future feasibility studies to be conducted into the clinical use of dynamic subcutaneous lactate monitoring in trauma and resuscitation.

Type
Systematic Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of World Association for Disaster and Emergency Medicine

Introduction

Trauma is a leading cause of death and morbidity world-wide. Most deaths tend to occur within 48 hours of injury, with hemorrhage being a significant cause. Reference Alberdi, García and Atutxa1Reference Sauaia, Moore and Moore3 However, major trauma is no longer only a condition of the young, as trauma in the elderly population is on the rise. Reference Kehoe, Smith and Edwards4 More than five million people die each year due to their injuries, accounting for nine percent of deaths world-wide. 5 In England alone, there are an estimated 20,000 major trauma cases each year, with 5,400 subsequent deaths. 6 Early prehospital interventions are a current research focus, particularly on the use of biomarkers. One of those biomarkers is lactate.

Lactate is a known diagnostic and prognostic marker used in infection, trauma, and out-of-hospital cardiac arrest. Reference Régnier, Raux and Le Manach710 It has been associated with increased mortality, surgery requirement, and organ dysfunction. Reference Guyette, Suffoletto and Castillo11,Reference Baxter, Cranfield and Clark12 The Advanced Trauma Life Support (ATLS) course teaches four shock classes to diagnose and manage hypovolemic shock, which utilize estimated blood loss and patient vital signs, such as blood pressure, heart rate, respiratory rate, as well as urine output and mental status. 13 However, questions have been raised over its value in the initial diagnosis and management of shock. Reference Vandromme, Griffin and Weinberg14,Reference Mutschler, Paffrath and Wölfl15 Vital signs are known to respond late to intervention and a change in clinical stability, particularly in acute hemorrhage, and may not accurately reflect the patient’s current hemodynamic status. Reference Guyette, Suffoletto and Castillo11,Reference Vandromme, Griffin and Weinberg14,Reference Connelly and Schreiber16,Reference Bar-Or, Salottolo and Orlando17

Serum lactate concentration has been correlated with the presence of shock, and trend increases in prehospital lactate have been strongly associated with the need for prehospital life-saving interventions. Reference Galvagno, Sikorski and Floccare18Reference Canton, Lutfi and Daley20 Lactate clearance (through serial lactate measurement) can provide data on the adequacy of initial resuscitation in trauma and aid in prognostication. Reference Régnier, Raux and Le Manach7,Reference Lewis, Naumann and Crombie21,Reference Dübendorfer, Billeter and Seifert22 Serial lactate measurement enables monitoring of the response to administered prehospital therapy and has been evidenced to increase survival in the intensive care setting. Reference Jansen, van Bommel and Mulder23Reference van Beest, Brander and Jansen26 The use of point-of-care (POC) testing in both the prehospital and in-hospital environment allows for this periodic assessment of lactate; however, there is an associated expense and labor requirement for repeated sampling. The introduction of subcutaneous continuous lactate monitoring (SCLM) would provide a constant and consistent opportunity to monitor and utilize the telemetry trend to guide management.

The National Institute for Health and Care Excellence (NICE; London, United Kingdom) has published research recommendation NG39/2, which aims to determine the clinical and cost-effectiveness of lactate monitoring in major trauma, and highlights the need for additional research. 27 This systematic review aims to summarize and appraise the current literature related to the use of SCLM in trauma patients in the prehospital environment. The review findings will then focus the future research proposals in this innovative area.

Study Question

The primary question in this study was: “Is prehospital subcutaneous continuous lactate monitoring in adult trauma patients clinically and cost-effective compared to the standard methods of guiding resuscitation?”

Methodology

This systematic review has been devised and conducted in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) 2020 guidelines. Reference Page, McKenzie and Bossuyt28 The protocol for this systematic review was registered with PROSPERO (University of York; York, United Kingdom; CRD42022320900). An error was made in the initially uploaded protocol. In the uploaded document, the PubMed (National Center for Biotechnology Information, National Institutes of Health; Bethesda, Maryland USA) search strategy contained the terms “pre hospital” and “out of hospital” twice. One of each term was initially missing the hyphen. Hyphens were added and corrected before the search was run. The updated document uploaded to PROSPERO and indexed in this manuscript indicates the true search strategy.

PICO Statement

The population investigated were adult patients (≥ 16 years old) experiencing a traumatic injury and undergoing prehospital resuscitation. The intervention of interest was dynamic SCLM, facilitating lactate-guided resuscitation. The comparator group were those undergoing alternative methods of guided resuscitation. Outcomes were based on mortality, length of hospital and critical care stay, and the quantity and type of resuscitation fluids and blood products received.

Eligibility Criteria

All criteria were agreed upon before beginning data collection. Manuscripts detailing the use of subcutaneous lactate monitoring in the prehospital environment in adult (≥ 16 years old) trauma patients were eligible. Eligible manuscripts had to show evidence of dynamic monitoring being utilized for goal-directed therapy. A prior scoping review revealed evidence of limited studies, so all study types were included. No date requirements were set. Animal and non-human studies, manuscripts where the full text could not be sourced, and non-English language manuscripts were excluded.

Data Sources and Search Strategy

Searched databases included PubMed, EMBASE via Ovid SP (Elsevier; Amsterdam, Netherlands), Cochrane Library (Wiley; Hoboken, New Jersey USA), and Web of Science (Clarivate Analytics; London, United Kingdom). Search terms included MeSH and tiab terms with keywords including “trauma,” “injury,” “continuous lactate,” “subcutaneous lactate,” “dynamic lactate,” “pre-hospital,” “prehospital,” “pre hospital,” “out-of-hospital,” and “out of hospital.” Table 1 demonstrates the complete search strategy for each database. All databases were searched from inception, with restrictions to include only English-language publications. The final search was carried out on March 29, 2022. The references of all relevant manuscripts were also screened to detect any other appropriate publications.

Table 1. Search Strategy for the Chosen Databases and Date Periods

Data Selection

Search results were combined using EndNote (Clarivate Analytics; Philadelphia, Pennsylvania USA) and duplicates were removed. All unique manuscripts were uploaded to the Rayyan interface, Reference Ouzzani, Hammady and Fedorowicz29 and titles and abstracts were obtained for each manuscript. One author (JS) initially screened all the titles and abstracts according to the proposed eligibility criteria and irrelevant or incomplete results were removed. The second author (EB) then independently verified the screened manuscripts.

The full text was sourced for all manuscripts consistent with the eligibility criteria or where further reading was needed before a decision could be made. Each full-text manuscript was assessed against the complete inclusion and exclusion criteria by one author (JS) and a decision was made. A second author (EB) independently verified the study selection process. The authors maintained contact throughout, and no disagreements were made following the screening process. For excluded articles, a rationale for exclusion was recorded (Table 2).

Table 2. Manuscripts that Underwent Full-Text Review with Rationales for Exclusion

Data Extraction

The authors planned to extract all required data into a Microsoft Excel spreadsheet (Microsoft Corporation; Redmond, Washington USA). This process was to be carried out by one author, and the data then independently confirmed by the second author.

The process was intended to extract study-level data, including first author, publication date, country of origin, study design, and study size; patient-level data, including patient demographics, mechanism of injury, injury severity, method of guiding resuscitation, lactate concentration, volume and type of intravenous (IV) fluid administered, volume and type of blood products administered, and any other treatments received; and outcome measures, including survival to hospital discharge, prehospital patient mortality, in-hospital patient mortality, length of hospital stay, and length of critical care stay.

Risk of Bias and Certainty of Evidence

The Critical Appraisal Skills Programme (CASP) Checklists 30 were designated to assess the risk of bias for each relevant manuscript across multiple domains. The CASP checklists consist of specific criteria dependent on the research type, with a checklist available for each. One author was expected to complete a CASP checklist for each relevant manuscript, with a second author independently verifying the results. A risk of bias table was planned to summarize the findings.

Data Synthesis

Due to the anticipated heterogenicity of the findings, the authors planned to synthesize the data and demonstrate the results through a narrative review in a tabulated format in accordance with PRISMA guidelines. To confirm statistical heterogenicity, forest plots were to be used and visually inspected, with the degree of overlap in confidence intervals and appearance of outliers then used to gauge the level of heterogeneity.

Key data extracted from the manuscripts would be summarized and displayed using evidence tables. The heterogenicity of the findings, effect of the intervention, and risk of bias would be compiled and presented using narrative and visual formats.

Results

Six hundred manuscripts were identified across all searched databases, with 551 results after removing duplicates. Fourteen studies were identified as potentially relevant following title and abstract screening (Table 2). The full text was available for all 14 studies. After screening using the specified eligibility criteria, none of the relevant studies fully met the criteria. Figure 1 demonstrates the screening process in a PRISMA flow diagram. Reference Page, McKenzie and Bossuyt28

Figure 1. PRISMA Flowchart Demonstrating the Study Selection Process.

Discussion

The results of this systemic review confer with the initial findings of limited published evidence on the utility of dynamic SCLM in adult trauma. Of the 14 manuscripts that underwent full-text review, most examined the use of capillary or venous lactate as a prognostic marker and to guide trauma triage. No studies evaluated the use of subcutaneous lactate monitoring, nor did they determine the clinical efficacy of dynamic lactate-guided resuscitation.

This empty review highlights a clear gap in current evidence of the efficacy and cost-effectiveness of dynamic lactate monitoring in adult trauma patients through continuous subcutaneous monitoring. Lewis, et al Reference Lewis, Naumann and Crombie21 found in a 2016 systematic review that prehospital POC lactate monitoring showed evidence of feasibility and clinical utility, especially within the first 15 minutes of emergency services arrival. They argued that with an estimated half-life of 20 minutes, dynamic lactate monitoring may highlight a persistent state of hypoxia requiring additional resuscitative measures. Therefore, SCLM would permit the early identification of this state and expedite corrective treatment. Whilst repetitive POC lactate testing can provide a periodic assessment of lactate concentration and clearance, the lack of dynamic monitoring and the over-reliance on repeat user testing can be troublesome.

Serial Lactate Monitoring and Lactate-Guided Resuscitation

Lactate is a proven diagnostic marker in trauma, even in those displaying no clinical features of shock. Reference Jansen, van Bommel and Mulder23,Reference Caputo, Fraser and Paliga31 The variation in lactate from responder arrival at the scene to patient arrival at the emergency department has been evidenced as an independent prognostic marker, even after vital signs have been accounted for. Reference Jansen, van Bommel and Mulder23 Multiple sources have denoted the use of lactate as a clinically relevant endpoint in resuscitation in polytrauma patients and its use in guiding resuscitation. Reference Régnier, Raux and Le Manach7,Reference Jansen, van Bommel and Mulder23,Reference Gonzalez-Robledo, Martin-Gonzalez and Moreno-Garcia32 In a multicenter, open-label, randomized controlled trial based in the intensive care unit (ICU), Jansen, et al Reference Jansen, van Bommel and Schoonderbeek25 found that lactate-guided therapy decreased in-hospital mortality, inotrope use, time on mechanical ventilation, and length of ICU stay.

Recent evidence has shown that hyperlactatemia is not exclusive to anaerobic conditions but can also result from aerobic glycolysis, independent of tissue hypoxia, via beta-adrenergic stimulation. Pain and stress are two ever-present factors in prehospital trauma patients, both of which increase the stimulation of beta-adrenergic receptors through the release of adrenaline. Reference Griggs and Wijesuriya33,Reference Kushimoto, Akaishi and Sato34 This link has subsequently been demonstrated by a reduction in venous lactate in prehospital trauma patients who received IV analgesia before lactate testing. Reference Griggs and Wijesuriya33 Beta-adrenergic agonists can also lead to a raised lactate and may hinder lactate-guided resuscitation in certain situations, such as traumatic cardiac arrest, where adrenaline is administered. Reference Czempik, Gierczak and Wilczek35 There are several other confounding factors that may alter lactate concentration, including the presence of isolated injuries, IV fluids, hyperglycemia, as well as alcohol intake. Reference Griggs and Wijesuriya33,Reference Dezman, Comer and Narayan36 Lactate clearance is predominantly mediated through direct utilization by the brain, heart, and skeletal muscle and by the conversion to glucose through the Cori cycle, which takes place in the liver. Reference Soeters, Shenkin and Sobotka37 Hepatic and renal dysfunction both contribute to reduced lactate clearance. Reference Cheng, Kung and Wu38 These confounding factors pose a challenge to the utility of lactate as a resuscitation endpoint prehospitally, as relatively little background is known, and the involvement of alcohol and narcotics may be undetermined.

The current literature on the use of lactate-guided resuscitation in the prehospital environment is sparse. As mentioned previously, the 2016 systematic review by Lewis, et al Reference Lewis, Naumann and Crombie21 exploring prehospital POC lactate following trauma concluded that lactate-guided resuscitation had not been tested in the prehospital environment. The authors could find no further studies directly examining the use of prehospital lactate-guided resuscitation.

Subcutaneous Lactate Monitoring Devices

Minimally invasive biosensor patches have demonstrated good efficacy in measuring the lactate concentration of interstitial fluid (ISF) in real time. These novel devices are yet to reach the market, however, clinical trials have revealed good patient acceptability, and close correlation with venous lactate concentration and dynamics, with a lag time of around five minutes. Reference Ming, Jangam and Gowers39,Reference Dror, Weidling and White40 These studies demonstrated the clinical efficacy of the devices on healthy volunteers undergoing 30 minutes of moderate exercise to increase serum lactate concentration. However, a potential downfall identified is that ISF lactate clearance in the skin may be slower compared to the blood. Physiological variability, reduced skin perfusion, and differences in activity baseline may contribute to this phenomenon. Reference Ming, Jangam and Gowers39 This issue of decreased tissue perfusion raises an important point: trauma patients experiencing hypovolemic shock are, by definition, hypo-perfusing their tissues. Consequently, this may lead to artificially high ISF lactate levels, despite a falling serum concentration.

In contrast, a study by Kopterides, et al Reference Kopterides, Theodorakopoulou and Ilias41 found the opposite. Using micro-dialysis catheters placed into the subcutaneous tissues of mechanically ventilated patients, they found tissue lactate to be better correlated to venous lactate in shocked patients compared to those who were not shocked. They also found that tissue lactate changes may precede changes in serum lactate, signaling an opportunity for subcutaneous lactate monitors to trigger earlier clinical intervention. Ultimately, these novel devices require further clinical trials in acutely unwell patients to determine their efficacy in hypoperfused states and at predicting lactate trends.

Future Advancements

Further research is necessary on the utility of lactate-guided resuscitation in prehospital trauma patients and the use of dynamic monitoring. Ultimately, SCLM provides a safe, easy, and consistent method of lactate monitoring, with reasonable accuracy and acceptable lag times. However, the current unavailability of commercial monitors means that clinical data are somewhat limited. Additionally, the cost is a notable issue. Newly developed technology typically carries an inflated price tag, as seen with the introduction of subcutaneous glucose monitors. However, this cost is now decreasing secondary to increased manufacturing and market competition. With the development of functioning continuous lactate monitoring prototypes, an evolution in the accessibility and utility of this technology will hopefully be seen in the coming years.

Limitations

This review found no relevant literature on the area of interest. This is presumed to be due to the lack of current evidence or data, however, manuscripts may not have been identified by the search strategy. Despite this, steps were taken to avoid missing data through a thorough search strategy and the review of all the referenced manuscripts from the 14 that underwent full-text review. With no data, a conclusion cannot be drawn for or against the clinical utility of SCLM. Nevertheless, it reveals a significant literature gap and highlights an opportunity for further research and development.

Conclusions

Little is known about the utility of SCLM in adult trauma, and this review highlights a clear gap in current literature. Novel subcutaneous lactate monitors have shown a close correlation with venous lactate whilst providing a dynamic reading with acceptable lag times; however, their commercial availability and cost remain a potential barrier. This lack of data evidences the feasibility of further research into their use in trauma and in guiding resuscitation. Other studies have demonstrated the benefits of lactate-guided resuscitation in-hospital, but a number of confounding factors need to be considered when applying this technology to the prehospital environment.

Conflicts of interest/funding

The authors declare none. There are no financial conflicts of interest to disclose.

Acknowledgments

The authors thank Dr. John Glen, MBChB, BSc (Hons), MRCP, FRCA, FFICM, DipRTM(RCSEd), PGCME (Consultant in Anesthesia and Intensive Care Medicine, Ysbyty Glan Clwyd, Betsi Cadwaladr University Health Board) for his knowledge and direction.

Supplementary Materials

To view supplementary material for this article, please visit https://doi.org/10.1017/S1049023X23006623

References

Alberdi, F, García, I, Atutxa, L, et al. Epidemiology of severe trauma. Med Intensiva Engl Ed. 2014;38(9):580588.CrossRefGoogle ScholarPubMed
Bozzette, A, Aeron-Thomas, A. Reducing trauma deaths in the UK. The Lancet. 2013;382(9888):208.CrossRefGoogle ScholarPubMed
Sauaia, A, Moore, FA, Moore, EE, et al. Epidemiology of trauma deaths: a reassessment. J Trauma Inj Infect Crit Care. 1995;38(2):185193.CrossRefGoogle ScholarPubMed
Kehoe, A, Smith, JE, Edwards, A, et al. The changing face of major trauma in the UK. Emerg Med J. 2015;32(12):911915.CrossRefGoogle ScholarPubMed
World Health Organization. Injuries and violence: the facts. 2014. https://www.who.int/publications/i/item/9789241508018. Accessed August 2023.Google Scholar
National Audit Office. Major trauma care in England: report by the comptroller and auditor general. 2010. https://www.nao.org.uk/wp-content/uploads/2010/02/0910213.pdf. Accessed August 2023.Google Scholar
Régnier, M-A, Raux, M, Le Manach, Y, et al. Prognostic significance of blood lactate and lactate clearance in trauma patients. Anesthesiology. 2012;117(6):12761288.CrossRefGoogle ScholarPubMed
Jones, AE. Lactate clearance in the acutely traumatized patient. Anesthesiology. 2012;117(6):11621164.CrossRefGoogle ScholarPubMed
Lee, SG, Song, J, Park, DW, et al. Prognostic value of lactate levels and lactate clearance in sepsis and septic shock with initial hyperlactatemia: a retrospective cohort study according to the Sepsis-3 definitions. Medicine (Baltimore). 2021;100(7):e24835.CrossRefGoogle Scholar
The CRITICAL Study Group Investigators; Nishioka N, Kobayashi D, et al. Association between serum lactate level during cardiopulmonary resuscitation and survival in adult out-of-hospital cardiac arrest: a multicenter cohort study. Sci Rep. 2021;11(1):1639.CrossRefGoogle Scholar
Guyette, F, Suffoletto, B, Castillo, JL, et al. Prehospital serum lactate as a predictor of outcomes in trauma patients: a retrospective observational study. J Trauma. 2011;70(4):782786.Google ScholarPubMed
Baxter, J, Cranfield, KR, Clark, G, et al. Do lactate levels in the emergency department predict outcome in adult trauma patients? A systematic review. J Trauma Acute Care Surg. 2016;81(3):555566.CrossRefGoogle ScholarPubMed
Committee on Trauma, American College of Surgeons. Advanced Trauma Life Support: Student Course Manual. Chicago, Illinois USA: American College of Surgeons; 2018.Google Scholar
Vandromme, MJ, Griffin, RL, Weinberg, JA, et al. Lactate is a better predictor than systolic blood pressure for determining blood requirement and mortality: could prehospital measures improve trauma triage? J Am Coll Surg. 2010;210(5):861867.CrossRefGoogle ScholarPubMed
Mutschler, M, Paffrath, T, Wölfl, C, et al. The ATLS classification of hypovolemic shock: a well-established teaching tool on the edge? Injury. 2014;45:S35S38.CrossRefGoogle ScholarPubMed
Connelly, CR, Schreiber, MA. Endpoints in resuscitation. Curr Opin Crit Care. 2015;21(6):512519.CrossRefGoogle ScholarPubMed
Bar-Or, D, Salottolo, KM, Orlando, A, et al. Association between a geriatric trauma resuscitation protocol using venous lactate measurements and early trauma surgeon involvement and mortality risk. J Am Geriatr Soc. 2013;61(8):13581364.CrossRefGoogle ScholarPubMed
Galvagno, SM, Sikorski, RA, Floccare, DJ, et al. Prehospital point of care testing for the early detection of shock and prediction of life-saving interventions. Shock. 2020;54(6):710716.CrossRefGoogle Scholar
Jonishi, K, Sakamoto, Y, Ueno, Y, et al. Examination of the utility of serum lactate and base deficit in hemorrhagic shock. Crit Care. 2010;14(Suppl 1):P161.CrossRefGoogle Scholar
Canton, SP, Lutfi, W, Daley, BJ, et al. Lactate as a mediator of prehospital plasma mortality reduction in hemorrhagic shock. J Trauma Acute Care Surg. 2021;91(1):186191.CrossRefGoogle ScholarPubMed
Lewis, CT, Naumann, DN, Crombie, N, et al. Prehospital point-of-care lactate following trauma: a systematic review. J Trauma Acute Care Surg. 2016;81(4):748755.CrossRefGoogle ScholarPubMed
Dübendorfer, C, Billeter, AT, Seifert, B, et al. Serial lactate and admission SOFA scores in trauma: an analysis of predictive value in 724 patients with and without traumatic brain injury. Eur J Trauma Emerg Surg. 2013;39(1):2534.CrossRefGoogle ScholarPubMed
Jansen, TC, van Bommel, J, Mulder, PG, et al. The prognostic value of blood lactate levels relative to that of vital signs in the pre-hospital setting: a pilot study. Crit Care. 2008;12(6):R160.CrossRefGoogle ScholarPubMed
Krishna, U, Joshi, SP, Modh, M. An evaluation of serial blood lactate measurement as an early predictor of shock and its outcome in patients of trauma or sepsis. Indian J Crit Care Med. 2009;13(2):6673.CrossRefGoogle ScholarPubMed
Jansen, TC, van Bommel, J, Schoonderbeek, FJ, et al. Early lactate-guided therapy in intensive care unit patients: a multicenter, open-label, randomized controlled trial. Am J Respir Crit Care Med. 2010;182(6):752761.CrossRefGoogle ScholarPubMed
van Beest, PA, Brander, L, Jansen, SP, et al. Cumulative lactate and hospital mortality in ICU patients. Ann Intensive Care. 2013;3(1):6.CrossRefGoogle ScholarPubMed
National Institute for Health and Care Excellence (NICE). Major trauma: assessment and initial management. Individual research recommendation details: NG39/2. 2016. https://www.nice.org.uk/guidance/ng39/resources/research-recommendations-from-an-individual-piece-of-guidance. Accessed August 2023.Google Scholar
Page, MJ, McKenzie, JE, Bossuyt, PM, et al. The PRISMA 2020 statement: an updated guideline for reporting systematic reviews. BMJ. 2021:n71.CrossRefGoogle Scholar
Ouzzani, M, Hammady, H, Fedorowicz, Z, et al. Rayyan—a web and mobile app for systematic reviews. Syst Rev. 2016;5(1):210.CrossRefGoogle ScholarPubMed
Critical Appraisal Skills Programme. CASP Systematic Review Checklist. 2022. https://casp-uk.net/casp-tools-checklists/. Accessed August 2023.Google Scholar
Caputo, N, Fraser, R, Paliga, A, et al. Triage vital signs do not correlate with serum lactate or base deficit, and are less predictive of operative intervention in penetrating trauma patients: a prospective cohort study. Emerg Med J. 2013;30(7):546550.CrossRefGoogle ScholarPubMed
Gonzalez-Robledo, J, Martin-Gonzalez, F, Moreno-Garcia, M, et al. Prognostic factors associated with mortality in patients with severe trauma: from prehospital care to the intensive care unit. Med Intensiva. 2015;39(7):412421.Google ScholarPubMed
ter Avest E, Griggs, J, Wijesuriya, J, et al. Determinants of prehospital lactate in trauma patients: a retrospective cohort study. BMC Emerg Med. 2020;20(1):18.Google Scholar
Kushimoto, S, Akaishi, S, Sato, T, et al. Lactate, a useful marker for disease mortality and severity but an unreliable marker of tissue hypoxia/hypoperfusion in critically ill patients. Acute Med Surg. 2016;3(4):293297.CrossRefGoogle ScholarPubMed
Czempik, PF, Gierczak, D, Wilczek, D, et al. The impact of red blood cell transfusion on blood lactate in non-bleeding critically ill patients—a retrospective cohort study. J Clin Med. 2022;11(4):1037.CrossRefGoogle ScholarPubMed
Dezman, ZDW, Comer, AC, Narayan, M, et al. Alcohol consumption decreases lactate clearance in acutely injured patients. Injury. 2016;47(9):19081912.CrossRefGoogle ScholarPubMed
Soeters, PB, Shenkin, A, Sobotka, L, et al. The anabolic role of the Warburg, Cori-cycle and Crabtree effects in health and disease. Clin Nutr. 2021;40(5):29882998.CrossRefGoogle ScholarPubMed
Cheng, C-Y, Kung, C-T, Wu, K-H, et al. Liver cirrhosis affects serum lactate level measurement while assessing disease severity in patients with sepsis. Eur J Gastroenterol Hepatol. 2021;33(9):12011208.CrossRefGoogle ScholarPubMed
Ming, DK, Jangam, S, Gowers, SAN, et al. Real-time continuous measurement of lactate through a minimally invasive microneedle patch: a phase I clinical study. BMJ Innov. 2022;8(2):8794.CrossRefGoogle Scholar
Dror, N, Weidling, J, White, S, et al. Clinical evaluation of a novel subcutaneous lactate monitor. J Clin Monit Comput. 2022;36(2):537543.CrossRefGoogle ScholarPubMed
Kopterides, P, Theodorakopoulou, M, Ilias, I, et al. Interrelationship between blood and tissue lactate in a general intensive care unit: a subcutaneous adipose tissue micro-dialysis study on 162 critically ill patients. J Crit Care. 2012;27(6):742.e9742.e18.CrossRefGoogle Scholar
Figure 0

Table 1. Search Strategy for the Chosen Databases and Date Periods

Figure 1

Table 2. Manuscripts that Underwent Full-Text Review with Rationales for Exclusion

Figure 2

Figure 1. PRISMA Flowchart Demonstrating the Study Selection Process.

Supplementary material: PDF

Scriven and Battaloglu supplementary material

Scriven and Battaloglu supplementary material

Download Scriven and Battaloglu supplementary material(PDF)
PDF 338.7 KB