article

Control of Patient Flow in Emergency Departments, or Multiclass Queues with Deadlines and Feedback

Authors:

Avishai MandelbaumAuthors Info & Claims

Operations Research, Volume 63, Issue 4

Pages 892 - 908

Published: 01 August 2015 Publication History

Abstract

We consider the control of patient flow through physicians in emergency departments EDs. The physicians must choose between catering to patients right after triage, who are yet to be checked, and those who are in process IP and are occasionally returning to be checked. Physician capacity is thus modeled as a queueing system with multiclass customers, where some of the classes face deadline constraints on their time-till-first-service, whereas the other classes feedback through service while incurring congestion costs. We consider two types of such costs: first, costs that are incurred at queue-dependent rates and second, costs that are functions of IP sojourn time. The former is our base model, which paves the way for the latter perhaps more ED realistic. In both cases, we propose and analyze scheduling policies that, asymptotically in conventional heavy traffic, minimize congestion costs while adhering to all deadline constraints. Our policies have two parts: the first chooses between triage and IP patients; assuming triage patients are chosen, the physicians serve the one who is closest to violating the deadline; alternatively, IP patients are served according to a G cµ rule, in which µ is simply modified to account for feedbacks. For our proposed policies, we establish asymptotic optimality, and develop some congestion laws snapshot principles that support forecasting of waiting and sojourn times. Simulation then shows that these policies outperform some commonly used ones. It also validates our laws and demonstrates that some ED features, the complexity of which reaches beyond our model e.g., time-varying arrival rates, leave without being seen LWBS or leave against medical advice LAMA, do not lead to significant performance degradation.

References

[1]

Allon G, Deo S, Lin W (2013) Impact of size and occupancy of hospital on the extent of ambulance diversion: Theory and evidence. Oper. Res. 61(3):544-562.

[2]

Armony M, Israelit S, Mandelbaum A, Marmor YN, Tseytlin Y, Yom-Tov GB (2015) Patient flow in hospitals: A data-based queueing-science perspective. Stochastic System . Forthcoming.

[3]

Ata B, Tongarlak HM (2013) On scheduling a multiclass queue with abandonments under general delay costs. Queueing Systems 74(1):65-104.

Digital Library

[4]

Atar R, Mandelbaum A, Zviran A (2012) Control of fork-join networks in heavy traffic. Proc. 50th Annual Allerton Conf. Comm., Control, Comput. (IEEE, Piscataway).

[5]

Batt RJ, Terwiesch C (2012) Doctors under load: An empirical study of state-dependent service times in emergency care. Working paper, The Wharton School, Philadelphia.

[6]

Batt RJ, Terwiesch C (2013) Waiting patiently: An empirical study of queue abandonment in an emergency department. Management Sci. 61(1):39-59.

Digital Library

[7]

Bäuerle N, Stidham S (2001) Conservation laws for single-server fluid networks. Queueing Systems 38(2):185-194.

[8]

Bolandifar E, DeHoratius N, Olsen T, Wiler JL (2014) Modeling the behavior of patients who leave the emergency department without being seen by a physician. Working paper, Chinese University of Hong Kong, Hong Kong.

[9]

Brailsford SC, Harper PR, Patel B, Pitt M (2009) An analysis of the academic literature on simulation and modelling in health care. J. Simulation 3(3):130-140.

[10]

Bramson M (1998) State space collapse with application to heavy traffic limits for multiclass queueing networks. Queueing Systems 30(1-2): 89-140.

Digital Library

[11]

Carmeli B (2012) Real time optimization of patient flow in emergency departments. M.Sc. Thesis, Technion--Israel Institute of Technology, Haifa.

[12]

Chen H, Shanthikumar JG (1994) Fluid limits and diffusion approximations for networks of multi-server queues in heavy traffic. Discrete Event Dynamic Systems 4(3):269-291.

[13]

Chen H, Yao DD (1993) Dynamic scheduling of a multiclass fluid network. Oper. Res. 41(6):1104-1115.

[14]

Chen H, Yao DD (2001) Fundamentals of Queuing Networks: Performance, Asymptotics, and Optimization (Springer, New York).

[15]

Dai JG, Kurtz TG (1995) A multiclass station with Markovian feedback in heavy traffic. Math. Oper. Res. 20(3):721-742.

Digital Library

[16]

Deo S, Gurvich I (2011) Centralized vs. decentralized ambulance diversion: A network perspective. Management Sci. 57(7):1300-1319.

Digital Library

[17]

Dobson G, Tezcan T, Tilson V (2013) Optimal workflow decisions for investigators in systems with interruptions. Management Sci. 59(5):1125-1141.

[18]

Farrohknia N, Castrén M, Ehrenberg A, Lind L, Oredsson S, Jonsson H, Asplund K, Göransson KE (2011) Emergency department triage scales and their components: A systematic review of the scientific evidence. Scandinavian J. Trauma, Resuscitation and Emergency Medicine 19:42.

[19]

Garnett O, Mandelbaum A, Reiman MI (2002) Designing a call center with impatient customers. Manufacturing Service Oper. Management 4(3):208-227.

Digital Library

[20]

Green LV, Soares J, Giglio JF, Green RA (2006) Using queuing theory to increase the effectiveness of emergency department provider staffing. Acad. Emergency Medicine 13:61-68.

[21]

Gurvich I, Whitt W (2009) Queue-and-idleness-ratio controls in many-server service systems. Math. Oper. Res. 34(2):363-396.

Digital Library

[22]

Hoot N, Aronsky D (2008) Systematic review of emergency department crowding: Causes, effects, and solutions. Ann. Emergency Medicine 52(2):126-136.

[23]

Huang J (2013) Patient flow management in emergency departments. Ph.D. Thesis, Technion--Israel Institute of Technology, Haifa, http://ie.technion.ac.il/serveng/References/Thesis_Junfei_Huang.pdf.

[24]

Ibrahim R, Whitt W (2009) Real-time delay estimation based on delay history. Manufacturing Service Oper. Management 11(3):397-415.

Digital Library

[25]

Kim J, Ward AR (2013) Dynamic scheduling of a GI/GI/1 + GI queue with multiple customer classes. Queueing Systems 75(2-4):339-384.

Digital Library

[26]

Klimov GP (1974) Time-sharing service systems. I. Theory Probab. Appl. 19(3):532-551.

[27]

Klimov GP (1978) Time-sharing service systems. II. Theory Probab. Appl. 23(2):314-321.

[28]

Liu Y, Whitt W (2012) The G _t/GI/s _t + GI many-server fluid queue. Queueing Systems 71(4):405-444.

Digital Library

[29]

Mace SE, Mayer TA (2008) Triage. Baren JM, Rothrock SG, Brennan JA, Brown L, eds. Pediatric Emergency Medicine , Chapter 155 (Elsevier, Philadelphia), 1087-1096.

[30]

Mandelbaum A, Massey WA (1995) Strong approximations for timedependent queues. Math. Oper. Res. 20(1):33-64.

Digital Library

[31]

Mandelbaum A, Stolyar AL (2004) Scheduling flexible servers with convex delay costs: Heavy-traffic optimality of the generalized c µ-rule. Oper. Res. 52(6):836-855.

Digital Library

[32]

Mandelbaum A, Zeltyn S (2009) Staffing many-server queues with impatient customers: Constraint satisfaction in call centers. Oper. Res. 57(5):1189-1205.

Digital Library

[33]

Marmor YN, Golany B, Israelit S, Mandelbaum A (2012) Designing patient flow in emergency departments. IIE Trans. Healthcare Systems Engrg. 2(4):233-247.

[34]

Niska R, Bhuiya F, Xu J (2010) National hospital ambulatory medical care survey: 2007 emergency department summary. National Health Statist. Rep. 26(August 6).

[35]

Pitts SR, Nawar EW, Xu J, Burt CW (2008). National hospital ambulatory medical care survey: 2006 emergency department summary. National Health Statist. Rep. 7(August 6).

[36]

Plambeck E, Kumar S, Harrison JM (2001) A multiclass queue in heavy traffic with throughput time constraints: Asymptotically optimal dynamic controls. Queueing Systems 39(1):23-54.

Digital Library

[37]

Reed JE, Ward AR (2008) Approximating the GI/GI/1CGI queue with a nonlinear drift diffusion: Hazard rate scaling in heavy traffic. Math. Oper. Res. 33:606-644.

Digital Library

[38]

Reiman MI (1982) The heavy traffic diffusion approximation for sojourn times in Jackson networks. Disney RL, Ott TJ, eds. Applied Probability and Computer Science--The Interface , Vol. 2 (Birkhäuser, Boston), 409-422.

[39]

Reiman MI (1984) Open queueing networks in heavy traffic. Math. Oper. Res. 9(3):441-458.

Digital Library

[40]

Reiman MI (1988) A multiclass feedback queue in heavy traffic. Adv. Appl. Probab. 20(1):179-207.

[41]

Saghafian S, Hopp WJ, Van Oyen MP, Desmond JS, Kronick SL (2012) Patient streaming as a mechanism for improving responsiveness in emergency departments. Oper. Res. 60(5):1080-1097.

Digital Library

[42]

Saghafian S, Hopp WJ, Van Oyen MP, Desmond JS, Kronick SL (2014) Complexity-augmented triage: A tool for improving patient safety and operational efficiency. Manufacturing Service Oper. Management 16(3):329-345.

Digital Library

[43]

van Mieghem JA (1995) Dynamic scheduling with convex delay costs: The generalized c. rule. Ann. Appl. Probab. 5(3):809-833.

[44]

van Mieghem JA (2003) Due-date scheduling: Asymptotic optimality of generalized longest queue and generalized largest delay rules. Oper. Res. 51(1):113-122.

Digital Library

[45]

Ward A (2011) Asymptotic analysis of queueing systems with reneging: A survey of results for FIFO, single class models. Surveys Oper. Res. Management Sci. 16:1-14.

[46]

Ward A, Glynn P (2005) A diffusion approximation for a GI/GI/1 queue with balking or reneging. Queueing Systems 50:371-400.

Digital Library

[47]

Ward AR, Kumar S (2008) Asymptotically optimal admission control of a queue with impatient customers. Math. Oper. Res. 33(1):167-202.

Digital Library

[48]

Whitt W (2002) Stochastic-Process Limits: An Introduction to Stochastic-Process Limits and Their Application to Queues (Springer, New York).

[49]

Wiler JL, Gentle C, Halfpenny JM, Heins A, Mehrotra A, Mikhail MG, Fite D (2010) Optimizing emergency department front-end operations. Ann. Emergency Medicine 55(2):142-160.

[50]

Williams RJ (1998) An invariance principle for semimartingale reflecting Brownian motion. Queueing Systems 30(1-2):5-25.

[51]

Yom-Tov GB, Mandelbaum A (2014) Erlang-R: A time-varying queue with ReEntrant customers, in support of healthcare staffing. Manufacturing Service Oper. Management 16(2):283-299.

[52]

Zaied I (2012) The offered load in Fork-Join networks: Calculations and applications to service engineering of emergency department. M.Sc. Thesis, Technion--Israel Institute of Technology, Haifa, http://ie.technion.ac.il/serveng/References/Thesis_Itamar_Zaied.pdf.

[53]

Zayas-Caban G, Xie J, Green LV, Lewis ME (2013) Optimal control of an emergency room triage and treatment process. Working paper, Cornell University, Ithaca, NY.

Cited By

Ding YGupta DTang X(2023)Early Reservation for Follow-up Appointments in a Slotted-Service QueueOperations Research10.1287/opre.2022.229971:3(917-938)Online publication date: 1-May-2023
https://dl.acm.org/doi/10.1287/opre.2022.2299
Li YWang HLi LFu Y(2021)Dynamic Large-Scale Server Scheduling for IVF Queuing Network in Cloud Healthcare SystemComplexity10.1155/2021/66702882021Online publication date: 21-Jan-2021
https://dl.acm.org/doi/10.1155/2021/6670288
Long ZShimkin NZhang HZhang J(2020)Dynamic Scheduling of Multiclass Many-Server Queues with AbandonmentOperations Research10.1287/opre.2019.190868:4(1218-1230)Online publication date: 22-May-2020
https://dl.acm.org/doi/10.1287/opre.2019.1908
Show More Cited By

Recommendations

Fluid Models for Multiserver Queues with Abandonments

Deterministic fluid models are developed to provide simple first-order performance descriptions for multiserver queues with abandonment under heavy loads. Motivated by telephone call centers, the focus is on multiserver queues with a large number of ...
On Poisson Approximations for Superposition Arrival Processes in Queues

We report on simulations of Σ_iGI_i/M/1 queues; the arrival process is the superposition sum of up to 1024 i.i.d. renewal processes and there is a single exponential server. As one might anticipate, the simulation estimate of the expected number of ...
Mt/G/∞ Queues with Sinusoidal Arrival Rates

In this paper we describe the mean number of busy servers as a function of time in an M_t/G/∞ queue having a nonhomogeneous Poisson arrival process with a sinusoidal arrival rate function. For an M_t/G/∞ model with appropriate initial conditions, it is ...

Comments

Please enable JavaScript to view thecomments powered by Disqus.

Information & Contributors

Information

Published In

cover image Operations Research

Operations Research Volume 63, Issue 4

August 2015

231 pages

ISSN:0030-364X

Issue’s Table of Contents

Publisher

INFORMS

Linthicum, MD, United States

Publication History

Published: 01 August 2015

Accepted: 01 March 2015

Received: 01 October 2012

Author Tags

Qualifiers

Article

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

7
Total Citations
View Citations
0
Total Downloads

Downloads (Last 12 months)0
Downloads (Last 6 weeks)0

Reflects downloads up to 13 Nov 2024

Other Metrics

View Author Metrics

Citations

Cited By

Ding YGupta DTang X(2023)Early Reservation for Follow-up Appointments in a Slotted-Service QueueOperations Research10.1287/opre.2022.229971:3(917-938)Online publication date: 1-May-2023
https://dl.acm.org/doi/10.1287/opre.2022.2299
Li YWang HLi LFu Y(2021)Dynamic Large-Scale Server Scheduling for IVF Queuing Network in Cloud Healthcare SystemComplexity10.1155/2021/66702882021Online publication date: 21-Jan-2021
https://dl.acm.org/doi/10.1155/2021/6670288
Long ZShimkin NZhang HZhang J(2020)Dynamic Scheduling of Multiclass Many-Server Queues with AbandonmentOperations Research10.1287/opre.2019.190868:4(1218-1230)Online publication date: 22-May-2020
https://dl.acm.org/doi/10.1287/opre.2019.1908
Chen JDong JShi P(2020)A survey on skill-based routing with applications to service operations managementQueueing Systems: Theory and Applications10.1007/s11134-020-09669-596:1-2(53-82)Online publication date: 4-Oct-2020
https://dl.acm.org/doi/10.1007/s11134-020-09669-5
Baron OBerman OKrass DWang J(2017)Strategic Idleness and Dynamic Scheduling in an Open-Shop Service NetworkManufacturing & Service Operations Management10.1287/msom.2016.059119:1(52-71)Online publication date: 1-Feb-2017
https://dl.acm.org/doi/10.1287/msom.2016.0591
Campello FIngolfsson AShumsky R(2017)Queueing Models of Case ManagersManagement Science10.1287/mnsc.2015.236863:3(882-900)Online publication date: 1-Mar-2017
https://dl.acm.org/doi/10.1287/mnsc.2015.2368
Zayas-Cabán GXie JGreen LLewis M(2016)Dynamic control of a tandem system with abandonmentsQueueing Systems: Theory and Applications10.1007/s11134-016-9489-784:3-4(279-293)Online publication date: 1-Dec-2016
https://dl.acm.org/doi/10.1007/s11134-016-9489-7

View Options

View options

Get Access

Login options

Check if you have access through your login credentials or your institution to get full access on this article.

Full Access

Get this Publication

Media

Figures

Other

Tables

View Issue’s Table of Contents