Modeling the impact of changing patient transportation systems on peri-operative process performance in a large hospital: insights from a computer simulation study

Segev, Danny; Levi, Retsef; Dunn, Peter F.; Sandberg, Warren S.

doi:10.1007/s10729-012-9191-1

Cited by 21 publications

(8 citation statements)

References 22 publications

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“…In such situations, computer-based simulation may be a powerful tool." The literature reports many successful simulations in healthcare domains (Berg et al, 2010;Clague et al, 1997;Dexter et al, 2000;Jun et al, 1999;Rohleder et al, 2011;Segev et al, 2012). Comparing parallel to non-parallel anesthesia processing in a controlled manner DES was a sensible choice.…”

Section: Simulation Modelmentioning

confidence: 99%

Improving operating room productivity via parallel anesthesia processing

Brown

Subramanian

Curry

et al. 2014

International Journal of Health Care Quality Assurance

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Section: Simulation Modelmentioning

confidence: 99%

Improving operating room productivity via parallel anesthesia processing

Brown

Subramanian

Curry

et al. 2014

International Journal of Health Care Quality Assurance

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“…Most of the other work focused on intrahospital routing focuses on deterministic problems . Beaudry et al consider a dynamic patient intrahospital transportation problem in which dynamic requests for patient transport must be served.…”

Section: Literature Reviewmentioning

confidence: 99%

Team orienteering with uncertain rewards and service times with an application to phlebotomist intrahospital routing

Jin¹,

Thomas

2019

Networks

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This study focuses on the intrahospital routing of phlebotomists at the University of Iowa Hospitals and Clinics (UIHC). Phlebotomists are responsible for drawing specimens from patients based on doctors' orders. The results of the analysis of these specimens play an important role in determining patient treatment. However, the demand for phlebotomists is likely to outpace supply over the next few years. Therefore, it is important to improve the efficiency of phlebotomists. In this paper, we formulate the phlebotomist intrahospital routing problem as a team orienteering problem with stochastic rewards and service times. The rewards and service times are particularly interesting as they are the result of a queueing process. We present an a priori solution approach and derive a method for efficiently sampling the value of a solution, a value that cannot be determined analytically. Finally, we demonstrate that our proposed approach outperforms the current practice at UIHC. KEYWORDShealthcare operations, heuristic, Markov decision process, phlebotomy, queueing, service routing INTRODUCTIONResearch shows that laboratory performance affects approximately 60%-70% of the most critical medical decisions related to admission, discharge, and the medication of inpatients [12]. Phlebotomists are a key part of these laboratory services. Phlebotomists primarily draw blood, urine, and other samples from patients and are in fact often the patients' only contact with medical laboratories. With an increasing demand for healthcare services, the demand for phlebotomists is expected to grow 25% between 2014 and 2024 [5]. With the demand for healthcare workers at an all-time high [21] and healthcare dominating the American Staffing Associations Skills Gap Index, a measure of the hardest to fill jobs [1], it seems unlikely that the demand for phlebotomists can be met. Thus, increasing the efficiency of phlebotomists will be crucial to avoid delays in the admissions, discharge, and medication of patients.With this need in mind, this study focuses on the intrahospital routing of phlebotomists. This study is specifically motivated by the Department of Pathology at the University of Iowa Hospitals and Clinics (UIHC). This problem falls into the emerging category of routing problems called service routing problems. In service routing problems, service providers are routed among various customer locations at which a service must be performed. In contrast to traditional routing problems, however, attributes of the particular provider performing the service and/or the attributes of the service to be provided lead to heterogeneous and often stochastic service times. In addition to the intrahospital routing problem studied in this paper, examples of service routing problems include home healthcare routing [32] and service technician routing [11]. In coming years, the set of such problems will only increase. This increase will in part be due to the ubiquity of data that will allow us to solve hidden routing problems such Networks. 2019;73:453-465....

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“…[40][41][42] Clinically active EM researchers have applied HF principles to the evaluation and improvement of systems of emergency care. 43 These investigations have led to insights into HF issues that affect vital ED processes and tasks, including patient transportation, 44 disaster response, 45,46 and the acquisition of essential clinical supplies. 47 Patient telemetry monitoring, a complex clinical process, exemplifies an active area of HF-based research, with a focus on alarm fatigue 48 and the timely detection of life-threatening arrhythmias.…”

Section: Hf In Emmentioning

confidence: 99%

Human Factors and Simulation in Emergency Medicine

Hayden

Wong

Ackerman

et al. 2017

Academic Emergency Medicine

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This consensus group from the 2017 Academic Emergency Medicine Consensus Conference "Catalyzing System Change through Health Care Simulation: Systems, Competency, and Outcomes" held in Orlando, Florida, on May 16, 2017, focused on the use of human factors (HF) and simulation in the field of emergency medicine (EM). The HF discipline is often underutilized within EM but has significant potential in improving the interface between technologies and individuals in the field. The discussion explored the domain of HF, its benefits in medicine, how simulation can be a catalyst for HF work in EM, and how EM can collaborate with HF professionals to effect change. Implementing HF in EM through health care simulation will require a demonstration of clinical and safety outcomes, advocacy to stakeholders and administrators, and establishment of structured collaborations between HF professionals and EM, such as in this breakout group.

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Modeling the impact of changing patient transportation systems on peri-operative process performance in a large hospital: insights from a computer simulation study

Cited by 21 publications

References 22 publications

Improving operating room productivity via parallel anesthesia processing

Improving operating room productivity via parallel anesthesia processing

Team orienteering with uncertain rewards and service times with an application to phlebotomist intrahospital routing

Human Factors and Simulation in Emergency Medicine

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