Si bien los equipos automatizados de cultivo microbiológico ofrecen mayor estandarización, reproducibilidad y potencial eficiencia en el flujo de trabajo, su adopción se ve obstaculizada por la complejidad de las muestras, los altos costos, las dificultados de integración, limitaciones de personal, obstáculos regulatorios y desafíos operativos. El objetivo del estudio fue analizar los retos en la adopción de equipos automatizados para cultivos. Se utilizó una metodología de estudio documental con un enfoque explicativo y de revisión bibliográfica. Recopilando información de artículos publicados en revistas indexadas en bases de datos como; Scopus, Biomed Central, Scielo y Science Direct. Los resultados revelaron que el desafío más comúnmente mencionado es la diversidad y la complejidad de las muestras. La adaptación del flujo de trabajo complejo surge como otro desafío, ya que se requieren modificaciones sustanciales en los procesos bien establecidos; La automatización ciertamente ha demostrado mejorar la precisión del diagnóstico en todos los contextos. Además, el alto rendimiento se logra a través de mecanismos complementarios; Los sistemas principales identificados son la WASP® de Copan, APAS Independence y BD Kiestra™ ReadA. Además, Clever Culture ha sido identificado en varios estudios. Se concluyó que la implementación de sistemas automatizados para cultivos bacteriológicos enfrenta desafíos multifactoriales que abarcan aspectos técnicos, regulatorios y operativos; La automatización en cultivos bacteriológicos demuestra un impacto positivo consistente en la precisión diagnóstica; El panorama actual de sistemas automatizados para cultivos bacteriológicos muestra una oferta tecnológica diversificada.

Culbreath K, Piwonka H, Korver J, Noorbakhsh M. Benefits Derived from Full Laboratory Automation in Microbiology: a Tale of Four Laboratories. J Clin Microbiol. 18 de febrero de 2021;59(3):e01969-20.

Thomson RB, McElvania E. Total Laboratory Automation: What Is Gained, What Is Lost, and Who Can Afford It? Clin Lab Med. 2020;39(3):371-89.

Huang Y, Sheth RU, Zhao S, Cohen LA, Dabaghi K, Moody T, et al. High-throughput microbial culturomics using automation and machine learning. Nat Biotechnol. 2023;41(10):1424-33.

The Business Research Company’s. Global Automated Blood Collection Market Forecast 2025-2034: Analyzing Growth Drivers, Share, Segments, And Trends. 2025 [citado 21 de junio de 2025]; Disponible en: https://www.thebusinessresearchcompany.com/report/automated-blood-collection-global-market-report

U.S. Automated Microbiology. Automated Microbiology Market Size to Hit USD 22.03 Billion by 2034 [Internet]. 2023 [citado 21 de junio de 2025]. Disponible en: https://www.precedenceresearch.com/automated-microbiology-market

Kenny C, Priyadarshini A. Review of Current Healthcare Waste Management Methods and Their Effect on Global Health. Healthcare (Basel). 5 de marzo de 2021;9(3):284.

Khalid S, Haq N, Sabiha Z ul A, Latif A, Khan MA, Iqbal J, et al. Current practices of waste management in teaching hospitals and presence of incinerators in densely populated areas. BMC Public Health. 7 de julio de 2021;21(1):1340.

Escobedo RLO, Ortiz-Chacha CS, Günther WMR, Arismendi RAA. Integral Waste Management in Primary Health Care centers: A Case Study in Mexico. Horizonte Sanitario. 3 de julio de 2021;20(3):349-55.

Chisholm JM, Zamani R, Negm AM, Said N, Abdel daiem MM, Dibaj M, et al. Sustainable waste management of medical waste in African developing countries: A narrative review. Waste Manag Res. 1 de septiembre de 2021;39(9):1149-63.

Shwetmala K, Arkalgud R, Anilkumar M. A roadmap for bio-medical waste management research. The International Journal of Health Planning and Management. 2021;36(4):1251-9.

Jain N, LaBeaud D. How Should US Health Care Lead Global Change in Plastic Waste Disposal? AMA Journal of Ethics. 1 de octubre de 2022;24(10):986-93.

Gupta PP, Bankar NJ, Mishra VH, Sanghavi S, Badge AK. The Efficient Disposal of Biomedical Waste Is Critical to Public Health: Insights from the Central Pollution Control Board Guidelines in India. Cureus. 2023;15(10):e47303.

Mazumder MAK, Abid MT, Fardousi A, Haque MM, Amin ZA, Rahman MS, et al. Assessment of hospital waste management practices in government and private tertiary hospitals in Dhaka, Bangladesh. [citado 22 de junio de 2025]; Disponible en: https://www.publichealthtoxicology.com/Assessment-of-hospital-waste-management-practices-nin-government-and-private-tertiary,177820,0,2.html

Yang T, Du Y, Sun M, Meng J, Li Y. Risk Management for Whole-Process Safe Disposal of Medical Waste: Progress and Challenges. Risk Manag Healthc Policy. 6 de junio de 2024;17:1503-22.

Alighardashi M, Mousavi SA, Almasi A, Mohammadi P. Hospital waste management system in Kermanshah: challenges, future and sustainable management with circular economy. Sci Rep. 27 de octubre de 2024;14(1):25671.

Amaike C, Olomojobi OV, Olusona I, Omoworare GE, Olu-Osayomi O, Ononuju S. Healthcare waste management in southwest Nigeria: a cross-sectional study among healthcare workers in a private tertiary hospital. PAMJ-One Health [Internet]. 8 de abril de 2025 [citado 22 de junio de 2025];16(12). Disponible en: https://www.one-health.panafrican-med-journal.com/content/article/16/12/full

van Altena AJ, Spijker R, Leeflang MMG, Olabarriaga SD. Training sample selection: Impact on screening automation in diagnostic test accuracy reviews. Res Synth Methods. noviembre de 2021;12(6):831-41.

Khavandi S, Zaghloul F, Higham A, Lim E, de Pennington N, Celi LA. Investigating the Impact of Automation on the Health Care Workforce Through Autonomous Telemedicine in the Cataract Pathway: Protocol for a Multicenter Study. JMIR Res Protoc. 5 de diciembre de 2023;12:e49374.

Jabbour S, Fouhey D, Shepard S, Valley TS, Kazerooni EA, Banovic N, et al. Measuring the Impact of AI in the Diagnosis of Hospitalized Patients. JAMA. 19 de diciembre de 2023;330(23):2275-84.

Al-Antari MA. Artificial Intelligence for Medical Diagnostics—Existing and Future AI Technology! Diagnostics (Basel). 12 de febrero de 2023;13(4):688.

Khavandi S, Zaghloul F, Higham A, Lim E, de Pennington N, Celi LA. Investigating the Impact of Automation on the Health Care Workforce Through Autonomous Telemedicine in the Cataract Pathway: Protocol for a Multicenter Study. JMIR Res Protoc. 5 de diciembre de 2023;12:e49374.

Rahman MdA, Victoros E, Ernest J, Davis R, Shanjana Y, Islam MdR. Impact of Artificial Intelligence (AI) Technology in Healthcare Sector: A Critical Evaluation of Both Sides of the Coin. Clin Pathol. 22 de enero de 2024;17:2632010X241226887.

Zuhair V, Babar A, Ali R, Oduoye MO, Noor Z, Chris K, et al. Exploring the Impact of Artificial Intelligence on Global Health and Enhancing Healthcare in Developing Nations. J Prim Care Community Health. 12 de abril de 2024;15:21501319241245847.

Kusunose K. Transforming Echocardiography: The Role of Artificial Intelligence in Enhancing Diagnostic Accuracy and Accessibility. Intern Med. 1 de febrero de 2025;64(3):331-6.

Gala D, Behl H, Shah M, Makaryus AN. The Role of Artificial Intelligence in Improving Patient Outcomes and Future of Healthcare Delivery in Cardiology: A Narrative Review of the Literature. Healthcare (Basel). 16 de febrero de 2024;12(4):481.

Maleki Varnosfaderani S, Forouzanfar M. The Role of AI in Hospitals and Clinics: Transforming Healthcare in the 21st Century. Bioengineering (Basel). 29 de marzo de 2024;11(4):337.

Takita H, Kabata D, Walston SL, Tatekawa H, Saito K, Tsujimoto Y, et al. A systematic review and meta-analysis of diagnostic performance comparison between generative AI and physicians. NPJ Digit Med. 22 de marzo de 2025;8:175.

Altheide ST. Biochemical and Culture-based Approaches to Identification in the Diagnostic Microbiology Laboratory. American Society for Clinical Laboratory Science. 2020;32(4):166-75.

Goneau LW, Mazzulli A, Trimi X, Cabrera A, Lo P, Mazzulli T. Evaluating the preservation and isolation of stool pathogens using the COPAN FecalSwabTM Transport System and Walk-Away Specimen Processor. Diagn Microbiol Infect Dis. 2020;94(1):15-21.

Brenton L, Waters MJ, Stanford T, Giglio S. Clinical evaluation of the APAS® Independence: Automated imaging and interpretation of urine cultures using artificial intelligence with composite reference standard discrepant resolution. J Microbiol Methods. octubre de 2020;177:106047.

Berneking L, Both A, Berinson B, Hoffmann A, Lütgehetmann M, Aepfelbacher M, et al. Performance of the BD Phoenix CPO detect assay for detection and classification of carbapenemase-producing organisms. Eur J Clin Microbiol Infect Dis. 2021;40(5):979-85.

Gao J, Chen Q, Peng Y, Jiang N, Shi Y, Ying C. Copan Walk Away Specimen Processor (WASP) Automated System for Pathogen Detection in Female Reproductive Tract Specimens. Front Cell Infect Microbiol. 2021;11:770367.

Gammel N, Ross TL, Lewis S, Olson M, Henciak S, Harris R, et al. Comparison of an Automated Plate Assessment System (APAS Independence) and Artificial Intelligence (AI) to Manual Plate Reading of Methicillin-Resistant and Methicillin-Susceptible Staphylococcus aureus CHROMagar Surveillance Cultures. J Clin Microbiol. 19 de octubre de 2021;59(11):e0097121.

Cherkaoui A, Schorderet D, Azam N, Crudeli L, Fernandez J, Renzi G, et al. Fully Automated EUCAST Rapid Antimicrobial Susceptibility Testing (RAST) from Positive Blood Cultures: Diagnostic Accuracy and Implementation. J Clin Microbiol. 60(10):e00898-22.

Dwivedi HP, Franklin S, Chandrasekaran S, Garner O, Traczewski MM, Beasley D, et al. Multicenter Clinical Evaluation of Vitek 2 Meropenem-Vaborbactam for Susceptibility Testing of Enterobacterales and Pseudomonas aeruginosa. J Clin Microbiol. 60(1):e01610-21.

Burns BL, Rhoads DD, Misra A. The Use of Machine Learning for Image Analysis Artificial Intelligence in Clinical Microbiology. J Clin Microbiol. 2023;61(9):e02336-21.

Jacot D, Gizha S, Orny C, Fernandes M, Tricoli C, Marcelpoil R, et al. Development and evaluation of an artificial intelligence for bacterial growth monitoring in clinical bacteriology. J Clin Microbiol. 62(5):e01651-23.

Cintrón M, Clark B, Miranda E, Babady NE. Utility of digital images captured after 4 h of incubation on a microbiology laboratory automation system in guiding the work-up of subcultures from positive blood cultures. J Clin Microbiol. 19 de febrero de 2025;63(2):e0132024.

Zimmermann S. Laboratory Automation in the Microbiology Laboratory: an Ongoing Journey, Not a Tale? J Clin Microbiol. 18 de febrero de 2021;59(3):e02592-20.

Antonios K, Croxatto A, Culbreath K. Current State of Laboratory Automation in Clinical Microbiology Laboratory. Clinical Chemistry. 1 de enero de 2022;68(1):99-114.

Schoffelen T, Papan C, Carrara E, Eljaaly K, Paul M, Keuleyan E, et al. European society of clinical microbiology and infectious diseases guidelines for antimicrobial stewardship in emergency departments (endorsed by European association of hospital pharmacists). Clinical Microbiology and Infection. 1 de noviembre de 2024;30(11):1384-407.

Plebani M. Quality in laboratory medicine and the Journal: walking together. Clin Chem Lab Med. 25 de abril de 2023;61(5):713-20.

Xie H, Jia Y, Liu S. Integration of artificial intelligence in clinical laboratory medicine: Advancements and challenges. Interdisciplinary Medicine. 2024;2(3):e20230056.

Toro W, Yang M, Patel A, Zhang S, Dabbous O, Garrison LP. Evolving Concept of Value in Health Economics and Outcomes Research: Emerging Tools for Innovation and Access to Cell and Gene Therapies for Rare Diseases. Value Health. mayo de 2025;28(5):686-91.