Stahl James E, Sandberg Warren S, Daily Bethany, Wiklund Richard, Egan Marie T, Goldman Julian M, Isaacson Keith B, Gazelle Scott, Rattner David W
Department of Medicine, Massachusetts General Hospital, Boston, Massachusetts 02114, USA.
Surgery. 2006 Jun;139(6):717-28. doi: 10.1016/j.surg.2005.12.006.
Many surgeons believe that long turnover times between cases are a major impediment to their productivity. We hypothesized that redesigning the operating room (OR) and perioperative-staffing system to take advantage of parallel processing would improve throughput and lower the cost of care.
A state of the art high tech OR suite equipped with augmented data collection systems served as a living laboratory to evaluate both new devices and perioperative systems of care. The OR suite and all the experimental studies carried out in this setting were designated as the OR of the Future Project (ORF). Before constructing the ORF, modeling studies were conducted to inform the architectural and staffing design and estimate their benefit. In phase I a small prospective trial tested the main hypothesized benefits of the ORF: reduced patient intra-operative flow-time, wait-time and operative procedure time. In phase II a larger retrospective study was conducted to explore factors influencing these effects. A modified process costing method was used to estimate costs based on nationally derived data. Cost-effectiveness was evaluated using standard methods.
There were 385 cases matched by surgeon and procedure type in the retrospective dataset (182 ORF, 193 standard operating room [SOR]). The median Wait Time (12.5 m ORF vs 23.8 m SOR), Operative Procedure Time (56.1 m ORF vs 70.5 m SOR), Emergence Time (10.9 m ORF vs 14.5 m SOR) and Total Patient OR Flowtime (79.5 m ORF vs 108.9 m SOR) were all shorter in the ORF (P < .05 for all comparisons). The median cost/patient was $3,165 in the ORF (interquartile range, $1,978 to $4,426) versus $2,645 in SORs (interquartile range, $1,823 to $3,908) (P = ns). The potential change in patient throughput for the ORF was 2 additional patients/day. This improved throughput was primarily attributable to a marked reduction in the non-operative time (ie, those activities commonly accounting for "turnover time") rather than facilitation of faster operations. The incremental cost-effectiveness ratio of ORF was $260 (interquartile range, $180 to $283).
The redesigned perioperative system improves patient flow, allowing more patients to be treated per day. Cost-effectiveness analysis suggests that the additional costs incurred by higher staffing ratios in an ORF environment are likely to be offset by increases in productivity. The benefits of this system are realized when performing multiple, short-to-medium duration procedures (eg, <120 m).
许多外科医生认为,手术之间较长的周转时间是影响其工作效率的主要障碍。我们假设重新设计手术室(OR)和围手术期人员配备系统以利用并行处理,将提高手术量并降低护理成本。
一个配备增强数据收集系统的先进高科技手术室套件作为一个实际实验室,用于评估新设备和围手术期护理系统。该手术室套件以及在此环境中进行的所有实验研究被指定为未来手术室项目(ORF)。在建造ORF之前,进行了建模研究,以指导建筑和人员配备设计并估计其效益。在第一阶段,进行了一项小型前瞻性试验,测试了ORF的主要假设效益:减少患者术中流动时间、等待时间和手术时间。在第二阶段,进行了一项更大规模的回顾性研究,以探索影响这些效果的因素。使用一种改进的过程成本核算方法,根据国家数据估算成本。使用标准方法评估成本效益。
回顾性数据集中有385例按外科医生和手术类型匹配的病例(182例ORF,193例标准手术室[SOR])。ORF组的中位等待时间(12.5分钟对23.8分钟SOR)、手术时间(56.1分钟对70.5分钟SOR)、苏醒时间(10.9分钟对14.5分钟SOR)和患者在手术室的总流动时间(79.5分钟对108.9分钟SOR)均较短(所有比较P <.05)。ORF组每位患者的中位成本为3165美元(四分位间距,1978美元至4426美元),而SOR组为2645美元(四分位间距,1823美元至3908美元)(P =无统计学意义)。ORF的患者手术量潜在变化为每天增加2名患者。这种手术量的提高主要归因于非手术时间(即通常占“周转时间”的那些活动)的显著减少,而不是手术速度加快。ORF的增量成本效益比为260美元(四分位间距,180美元至283美元)。
重新设计的围手术期系统改善了患者流程,使每天能够治疗更多患者。成本效益分析表明,ORF环境中较高人员配备比例所产生的额外成本可能会被生产率的提高所抵消。当进行多个短至中等时长的手术(例如,<120分钟)时,该系统的效益得以实现。
