Abstract
Objectives: Patient safety culture affects patient safety and the performance of hospitals. The Hospital Survey on Patient Safety Culture (HSOPSC) is generally used to assess the safety culture in hospitals and unit levels. However, only a few studies in China have measured surgical settings compared with other units in county hospitals using the HSOPSC. This study aims to assess the strengths and weaknesses of surgical departments compared with all other departments in county hospitals in China with HSOPSC. Design: This research is a cross-sectional study. Methods: In 2015, a Chinese translation of HSOPSC was administered to 1379 staff from sampled departments from 19 county hospitals in Xiaogan City (Hubei Province, China) using a simple random and cluster sampling method. Outcome Measures: The HSOPSC was completed by 1379 participants. The percent positive ratings (PPRs) of 12 dimensions (i.e., teamwork within units, organizational learning and continuous improvement, staffing, non-punitive response to errors, supervisor/ manager expectations and actions promoting patient safety, feedback and communication about errors, communication openness, hospital handoffs and transitions, teamwork across hospital units, hospital management support for patient safety, overall perception of safety, as well as frequency of events reported) and the positive proportion of outcome variables (patient safety grade and number of events reported) between surgical departments and other departments were compared with t-tests and X2 tests, respectively. A multiple regression analysis was conducted, with the outcome dimensions serving as dependent variables and basic characteristics and other dimensions serving as independent variables. Similarly, ordinal logistic regression was used to explore the influencing factors of two categorical outcomes. Results: A total of 56.49% of respondents were from surgical departments. The PPRs for “teamwork within units” and “organizational learning and continuous improvement” were ≥75%, which denoted strengths, and the PPRs for “staffing” and “non-punitive response to errors” were ≤50%, which denoted weaknesses in surgical units and other units. Three dimensions for surgical departments were weaker than those for other departments (p < 0.05). The staff from surgical units reported more events compared with the other units, but only a few respondents in surgical settings evaluated patient safety grade as good/excellent. Four dimensions influenced patient safety grade, and three dimensions influenced event reporting in surgical units. Conclusions: Strategies including recruiting workers, using the reporting system, and building a non-punitive culture should be adopted in the surgical units of county hospitals in China to improve safety culture. Supervisors should also prioritise patient safety.
Keywords: patient safety culture, HSOPSC, surgical departments, county hospitals
1. Introduction
Patient safety is considered to be crucial to health-care quality and is one of the major parameters monitored by all health-care organizations around the world [1]. In 1993, the UK Health and Safety Commission defined safety culture as the “product of the individual and group values, attitudes, competencies and patterns of behavior that determine the commitment to, and the style and proficiency of, an organization’s health and safety program” [2]. In 1998, Lucien, a pediatric surgeon and pioneer in the patient safety movement, described the prevailing safety culture as that of “anger, blame, frustration and distrust regarding health care errors” [3]. Since the release of the Institute of Medicine report “To Err is Human” [4], patient safety has received extensively increasing attention in many countries, including China. A positive safety culture improves hospitals’ patient safety performance, whereas a negative safety culture encourages hospitals to address issues in patient safety management [3]. Pronovost et al. asserted that assessing patient safety culture is the first step to improve safe care in hospitals [5]. Over the past decade, researchers have developed several instruments to evaluate patient safety culture [6,7,8]. Despite the largely independent development, these instruments feature similar psychometric properties and measure similar dimensions [9]. All these instruments use Likert scales, mostly measure attitudes of individuals, and nearly all cover five dimensions of patient safety climate, namely, leadership, policies as well as procedures, staffing, communication, and reporting [10]. One of these measurement tools is the Hospital Survey on Patient Safety Culture (HSOPSC), which was first introduced by the Agency of Healthcare Research and Quality (AHRQ) in America. The HSOPSC has been widely used because of its good reliability (Cronbach coefficient = 0.63–0.84) as well as validity (R = 0.23–0.60), detailed measurement structure, and unified quantitative standard [11].
An increasing number of studies have assessed patient safety culture, thereby revealing differences in patient safety culture across professions [12,13], units [14], hospitals [13,15], and countries [16]. In certain studies, unit-level assessment has emerged as a common topic. Many researchers have measured patient safety culture in intensive care units (ICUs) in their countries [17]. For example, Kho et al. [18] corroborated that three major safety themes require solutions: appropriate staffing, medication safety, and the improvement of the bedside care of obese patients. Other units’ patient safety culture [19,20,21] was also assessed by many scholars with different measurement tools. Liu [22] conducted a case study in an outpatient setting in China to measure its patient safety culture and affirmed that strong “teamwork within units”, a common area of strength, could fuel the concealment of errors. Hoffmann [23] carried out an open randomized controlled trial and evaluated the effects on patient safety culture in general practice. Other surveys assessed surgery and general practice units [20].
Surgical departments, including operating rooms, anesthesia units, obstetrics and gynecology departments, and other surgical units, are high hazard settings with a high potential for patient harm. The safety culture in these departments has been measured in certain studies. Bognár et al. [24] evaluated safety climate in a pediatric cardiac surgery unit, but they did not compare surgery units with the rest of the hospital units. Kaafarani et al. [25] assessed the patient safety culture in operating rooms and post-anesthesia units, but this survey was conducted with the Patient Safety Climate in Healthcare Organizations. Several studies measured surgical settings, particularly in China, using the HSOPSC. Our previous study [26] evaluated the patient safety culture in a surgical unit relative to that in other units on the basis of the HSOPSC, but we conducted the study in only one tertiary hospital. The research into safety culture in surgical units and operating rooms provides a reference for other departments. On the basis of previous studies, our research will continually reveal differences in patient safety culture across different departments in county hospitals.
Surgical departments in county hospitals consist of people with varying levels of expertise and highly advanced equipment, vulnerable patients, and limited time to treat patients [27]. In addition, surgical departments are complex and have high potential hazard for patient harm and adverse events [28]. More than half of all adverse events in hospitals (51–62%) occur in surgical settings [6,29]. Promoting highly reliable care in operating environments requires a strong patient safety culture [3]. Consequently, safety culture assessment in surgical departments is an urgent concern.
Xiaogan City is located in northeast Hubei Province, China. According to the Xiaogan Statistical Information Network, in 2014, Xiaogan City had an area of 8910 km2, and its resident population was 4.8661 million, and the regional gross domestic product (GDP) was 135.472 billion Renminbi (RMB). In 2014, Xiaogan City had a total of 423 health institutions (excluding village clinics), of which 45 were hospitals. It is one of the members of the Wuhan city circle and one of the most potential and competitive cities in the central region of China. The aim of our study was to examine the strengths and weaknesses of surgical departments compared with those of other departments in county hospitals in Xiaogan City of Hubei Province, China as well as to find out the factors affecting patient safety culture in hospitals at the county level. The results are expected to provide a reference for the policy makers and managers of county hospitals as they seek to improve patient safety culture in surgical settings by suggesting targeted recommendations for hospital unit levels on the basis of the HSOPSC.
2. Methods
2.1. Design
This study employed a cross-sectional survey.
2.2. Setting and Sampling
All 19 county hospitals in Xiaogan City located in northeast Hubei Province, China, were taken as the sample hospitals in this study. In 2015, the average in-service medical staff in these 19 county hospitals was 428, and the average open beds were 329. In the same year, the average diagnosis and treatment visits in the 19 hospitals were 190,543, of which 14,440 were outpatients. The average annual income of these 19 county hospitals was 108.28 million RMB in 2014. Subsequently, in every county hospital, the surgical departments (including the departments of general surgery, orthopedics, obstetrics and gynecology, emergency rooms, ICUs, urology, neurosurgery, and other comprehensive surgical units) and other hospital departments (referring to settings of most internal medicine units, traditional Chinese medicine, rehabilitation, nursing, B ultrasonic room, medical department, and other units) were selected with a simple random sampling method. All the doctors and nurses in the selected surgical departments and other departments were investigated using the HSOPSC with a cluster sampling method. Finally, 1379 questionnaires were collected, and all these 1379 questionnaires were deemed valid.
2.3. Instrument
The Chinese version of the HSOPSC was previously validated for paper distribution in our previous study [26]. The HSOPSC comprised 42 items, and the participants responded to the items on a five-point Likert scale ranging from “strongly disagree” to “strongly agree” or from “never” to “always”. The result variable “patient safety grade” was scored from 1 to 4 as follows: (1) excellent, (2) good, (3) acceptable, and (4) poor/failing. The result variable “number of events reported” by the respondents during the last 12 months was scored from 1 to 5: (1) “no events”, (2) “1 to 2 events”, (3) “3 to 5 events”, (4) “6 to 10 events”, and (5) “>10 events”. These two result variables are not part of the 42 items in the questionnaire, but were asked to be scored by the respondents separately.
The HSOPSC has well-established psychometric properties, including factor analysis, reliability, and item analysis [9,30]. To ensure that the concepts were correctly worded and conceptualized, we pilot-tested the readability and functionality of this questionnaire on several health-care workers and research personnel. After the pilot testing, factor analysis was conducted to measure the validity of the questionnaire in our previous study [26]. In the factor analysis, all 42 items were retained and divided into 12 dimensions, each of which included three to four items. The characteristics of the respondents were also included. The authors determined that the order of the questionnaire was not suitable for the habits of the Chinese. Accordingly, background information was moved to the beginning, and the questions on “patient safety grade” and “number of events reported” were moved toward the end of the questionnaire.
2.4. Data Collection
The study was carried out in August 2015. After receiving training in the hospital research department about the questionnaire’s content, the consultants went to the sample units from the 19 hospitals to distribute the questionnaires to the medical personnel. The timeline was set to 1 week, and the medical personnel received oral and e-mail reminders from the consultants every day until they completed the questionnaires. Some administrative staff and logistics staff didn’t participate in our survey because of the summer vacation, busy business and illnesses.
2.5. Statistical Analysis
We used Stata 14.0 (StataCorp, College Station, TX, USA) to analyze the data and replaced the missing values with the respondents’ mean scores on the items after evaluating the distribution of the 1–5 Likert scale. First, we descriptively analyzed the frequency and percentages of the sample respondents. Second, after reversing negatively worded items to make sure that positive answers presented a high score, the reliability and validity of the questionnaire structure were examined with factor analysis as well as Cronbach alpha. The percent positive ratings (PPRs) were then calculated among the hospital, surgical departments, and other departments. Answers of “agree” or “strongly agree” for the positively worded items indicated positive responses. The PPR refers to the proportion of the cumulative number of positive responses to each item and the total number of respondents. Moreover, the PPRs between the two department groups were compared on every dimension and every item with t-tests in an individual respondent level. Third, we used the Pearson X2 tests to compare the positive proportion of “patient safety grade” and “number of events reported” between the surgical departments and other departments. Fourth, after estimating the cluster effect of hospitals on the outcome dimensions, the factors affecting the “overall perceptions of safety”, “frequency of events reported”, and outcome variables of “patient safety grade” as well as “the number of events reported” were explored with multiple linear regression, two-level multiple regression, or two-level ordered logistic regression analysis [31] with basic characteristics and 10 other dimensions as independent variables. We tested for between-hospitals variation using the intraclass correlation coefficient (ICC), which represents the proportion of total variability in a given measure that can be attributed to differences between hospitals. It is equal to τ/(τ + σ2), where τ refers to between-hospitals variance and σ2 refers to within-staff variance [32]. Taking into consideration the potential clustering effect within hospitals, two-level regression models were applied afterward. In traditional regression models, it is assumed that observations are independent of each other, given the predictors. Multilevel models (also called hierarchical models or mixed-effects models) are developed for a specific situation wherein this independent assumption is not met: cluster-level attributes. That means observations are nested within subclassifications, and each subclassification has its own features. This is especially true in the context of Chinese hospitals, where medical staff working in the same hospital tend to have similar experience because they get together in the same team. The mathematical form of the 2-level multiple regression model is as follows:
Standard linear regression:
yi = β0 + β1X1i + β2X2i + … + βsXsi + ei, ei ~ N(0, δ2) | (1) |
Two-level linear regression:
yij = β0 + β1X1ij + β2X2ij + … + βsXsij + u0j + eij | (2) |
where i = 1, …, i is the staff level indicator, and j = 1, …, j is the hospital level indicator; y is the outcome dimensions; ei includes the estimated residual error of y and the hospital variation; u0j is the residual error. Similarly, the mathematical form of the 2-level logistic regression model [31] is as follows:
Standard Logistic Regression:
yij ~ Bern (1, πij) logit (πij) = α + βXij + Ɛij |
(3) |
Two-level logistic model:
yij ~ Bern (1, πij) logit (πij) = α0j + βXij + Ɛij α0j = α + μj |
(4) |
where i = 1, …, i is the staff level indicator, j = 1, …, j is the hospital level indicator, y is the result variables, πij is the probability of every option of result variables for staff i in hospital j, conditional on staff-level risk factors xij. The random effect model expresses that the logit is the sum of hospital-specific intercept αj and effects of staff-specific effects βXij, while the hospital intercept is a random variable with mean α and random variation μj ~ N(0, τ 2).
2.6. Ethical Consideration
Formal ethical approval was not needed for this study according to Chinese law. The respondents voluntarily participated in the survey. The consultants in the hospital research department managed the self-administered questionnaire with informed consent, and the returned questionnaires did not show identifying marks. The authors promised the absence of ethical issues, such as data fabrication, double publication, and plagiarism.
3. Results
3.1. Characteristics of Respondents
A total of 1379 participants completed the HSOPSC questionnaires. Of the 1379 participants, 779 (56.49%) were from surgical units, and 600 (43.51%) were from other units. The overall response rate was 91.93%. Table 1 shows the details on the characteristics of the respondents.
Table 1.
Characteristics | Kinds | Departments | |||
---|---|---|---|---|---|
Surgical Departments | Other Departments | ||||
n | % | n | % | ||
Staff position | Physician | 320 | 41.08 | 254 | 42.33 |
Nurse | 459 | 58.92 | 346 | 57.67 | |
Years in hospital | <1 year | 68 | 8.73 | 72 | 12.00 |
1–5 years | 296 | 38.00 | 233 | 38.83 | |
6–10 years | 151 | 19.38 | 111 | 18.50 | |
11–15 years | 82 | 10.53 | 55 | 9.17 | |
16–20 years | 81 | 10.40 | 66 | 11.00 | |
>21 years | 101 | 12.97 | 63 | 10.50 | |
Years in department | <1 year | 111 | 14.25 | 130 | 21.67 |
1–5 years | 329 | 42.23 | 281 | 46.83 | |
6–10 years | 129 | 16.56 | 91 | 15.17 | |
11–15 years | 90 | 11.55 | 41 | 6.83 | |
16–20 years | 60 | 7.70 | 28 | 4.67 | |
>21 years | 60 | 7.70 | 29 | 4.83 | |
Years in current profession | <1 year | 78 | 10.01 | 84 | 14.00 |
1–5 years | 379 | 48.65 | 304 | 50.67 | |
6–10 years | 163 | 20.92 | 113 | 18.83 | |
11–15 years | 84 | 10.78 | 50 | 8.33 | |
16–20 years | 42 | 5.39 | 27 | 4.50 | |
>21 years | 33 | 4.24 | 22 | 3.67 | |
Hours worked per week | <20 | 10 | 1.28 | 11 | 1.83 |
20–39 | 123 | 15.79 | 65 | 10.83 | |
40–59 | 447 | 57.38 | 343 | 57.17 | |
60–79 | 121 | 15.53 | 135 | 22.50 | |
80–99 | 50 | 6.42 | 29 | 4.83 | |
>100 | 28 | 3.59 | 17 | 2.83 | |
Average monthly income | <3000 RMB | 416 | 53.40 | 285 | 47.50 |
3000–5000 RMB | 323 | 41.46 | 275 | 45.83 | |
5000–8000 RMB | 37 | 4.75 | 36 | 6.00 | |
>8000 RMB | 3 | 0.39 | 4 | 0.67 | |
Contact with patients | Yes | 746 | 95.76 | 564 | 94.00 |
No | 33 | 4.24 | 36 | 6.00 |
Notes: HSOPSC is defined as the “Hospital Survey on Patient Safety Culture”. RMB is Renminbi.
3.2. Percent Positive Ratings (PPRs) of Surgical Departments Compared with Those of Other Departments
Factor analysis (KMO = 0.882) showed that the items within one factor did not load onto more than one factor. Initially, the items in this study appeared to form the same factors as the original questionnaire (Table 2) [6]. Additionally, the internal consistency was calculated for every factor, and the Cronbach alphas ranged from 0.31 to 0.87.
Table 2.
Kinds | Items | Hospital | Surgical Department | Other Departments | t | p | |||
---|---|---|---|---|---|---|---|---|---|
n | PPRs (%) | n | PPRs (%) | n | PPRs (%) | ||||
Unit level | Teamwork within units (Cronbach α = 0.67) | 4429 | 80.29 | 2512 | 80.62 a | 1917 | 79.88 a | 0.205 | 0.838 |
People support one another in this facility. | 1196 | 86.70 | 679 | 87.16 | 517 | 86.17 | 0.890 | 0.373 | |
When considerable work needs to be done quickly, we work together as a team to get the work done. | 1160 | 84.10 | 661 | 84.85 | 499 | 83.17 | 0.912 | 0.362 | |
In facility, people treat one another with respect. | 1178 | 85.40 | 657 | 84.34 | 521 | 86.83 | −0.868 | 0.385 | |
When one area in this unit gets extremely busy, others help out. | 895 | 64.90 | 515 | 66.11 | 380 | 63.33 | 0.427 | 0.670 | |
Organizational learning and continuous improvement (Cronbach α = 0.46) | 3274 | 79.14 | 1873 | 80.15 a | 1401 | 77.83 a | 0.707 | 0.480 | |
We are actively doing things to improve patient safety. | 1222 | 88.60 | 695 | 89.22 | 527 | 87.83 | 0.823 | 0.411 | |
Mistakes have led to positive changes here. | 1011 | 73.30 | 592 | 75.99 | 419 | 69.83 | 2.475 | 0.013 * | |
After we make changes to improve patient safety, we evaluate their effectiveness. | 1041 | 75.50 | 586 | 75.22 | 455 | 75.83 | −0.199 | 0.842 | |
Staffing (Cronbach α = 0.31) | 2026 | 36.73 | 1175 | 37.71 b | 851 | 35.46 b | 0.289 | 0.772 | |
We have enough staff to handle the workload. | 529 | 38.40 | 330 | 42.36 | 199 | 33.17 | 2.257 | 0.024 * | |
Staff in this unit work longer hours than is best for patient care. R | 152 | 11.00 | 79 | 10.14 | 73 | 12.17 | −1.491 | 0.136 | |
We use more agency/temporary staff than is best for patient care. R | 635 | 46.00 | 362 | 46.47 | 273 | 45.50 | 0.740 | 0.459 | |
We work in “crisis mode” trying to do too much, too quickly. R | 710 | 51.50 | 404 | 51.86 | 306 | 51.00 | −0.815 | 0.415 | |
Nonpunitive response to errors (Cronbach α = 0.48) | 1635 | 39.52 | 904 | 38.68 b | 731 | 40.61 b | −3.303 | 0.001 * | |
When an event is reported, it feels like the person is being written up, not the problem. R | 888 | 64.40 | 502 | 64.44 | 386 | 64.33 | −1.629 | 0.103 | |
Staff worry that mistakes they make are kept in their personnel file. R | 321 | 23.30 | 185 | 23.75 | 136 | 22.67 | −0.846 | 0.398 | |
Staff feel like their mistakes are held against them. R | 426 | 30.90 | 217 | 27.86 | 209 | 34.83 | −4.131 | <0.001 * | |
Supervisor/manager expectations and actions promoting patient safety (Cronbach α = 0.64) | 3882 | 70.38 | 2163 | 69.42 | 1719 | 71.63 | −2.479 | 0.013 * | |
Supervisor/manager says a good word when he/she sees a job done according to established guidelines. | 861 | 62.40 | 469 | 60.21 | 392 | 65.33 | −1.644 | 0.101 | |
My supervisor/manager seriously considers staff suggestions for improving patient safety. | 1041 | 75.50 | 591 | 75.87 | 450 | 75.00 | 0.333 | 0.739 | |
Whenever pressure builds up, my supervisor/manager wants us to work fast, even if it means taking shortcuts. R | 918 | 66.60 | 507 | 65.08 | 411 | 68.50 | −2.407 | 0.016 * | |
My supervisor/manager overlooks patient safety problems that happen over and over. R | 1062 | 77.00 | 596 | 76.51 | 466 | 77.67 | −1.058 | 0.290 | |
Feedback and communication about errors (Cronbach α = 0.61) | 2479 | 59.92 | 1425 | 60.98 | 1054 | 58.56 | 1.526 | 0.127 | |
We are given feedback about changes put into place on the basis of event reports. | 561 | 40.70 | 325 | 41.72 | 236 | 39.33 | 0.915 | 0.360 | |
In this unit, we discuss ways to prevent errors from recurring. | 1023 | 74.20 | 581 | 74.58 | 442 | 73.67 | 0.121 | 0.903 | |
We are informed about errors that happen in this unit. | 895 | 64.90 | 519 | 66.62 | 376 | 62.67 | 1.563 | 0.118 | |
Communication openness (Cronbach α = 0.79) | 2304 | 55.69 | 1307 | 55.93 | 997 | 55.39 | 0.450 | 0.653 | |
Staff will freely speak up if they see something that may negatively affect patient care. | 995 | 72.20 | 569 | 73.04 | 426 | 71.00 | 0.626 | 0.531 | |
Staff feel free to question the decisions or actions of those with substantial authority. | 406 | 29.40 | 221 | 28.37 | 185 | 30.83 | −0.066 | 0.948 | |
Staff are afraid to ask questions when something does not seem right. R | 903 | 65.50 | 517 | 66.37 | 386 | 64.33 | 0.353 | 0.724 | |
Hospital level | Hospital handoffs and transitions (Cronbach α = 0.68) | 3590 | 65.08 | 2038 | 65.40 | 1552 | 64.67 | −0.088 | 0.930 |
Important patient care information is commonly lost during shift changes. R | 1126 | 81.70 | 640 | 82.16 | 486 | 81.00 | −0.664 | 0.507 | |
Problems generally occur in the exchange of information across hospital units. R | 902 | 65.40 | 505 | 64.83 | 397 | 66.17 | −1.512 | 0.131 | |
Things “fall between the cracks” when transferring patients from one unit to another. R | 621 | 45.00 | 358 | 45.96 | 263 | 43.83 | 0.300 | 0.764 | |
Shift changes are problematic for patients in this hospital. R | 941 | 68.20 | 535 | 68.68 | 406 | 67.67 | 0.208 | 0.835 | |
Teamwork across hospital units (Cronbach α = 0.62) | 3604 | 65.34 | 2056 | 65.98 | 1548 | 64.50 | −0.541 | 0.588 | |
Working with staff from other hospital units is generally unpleasant. R | 1031 | 74.80 | 586 | 75.22 | 445 | 74.17 | −0.165 | 0.869 | |
Hospital units work well together to provide the best care for patients. | 918 | 66.60 | 531 | 68.16 | 387 | 64.50 | 0.177 | 0.860 | |
Good cooperation is present among hospital units that need to work together. | 769 | 55.80 | 431 | 55.33 | 338 | 56.33 | 0.072 | 0.943 | |
Hospital units do not coordinate well with one another. R | 886 | 64.20 | 508 | 65.21 | 378 | 63.00 | 0.031 | 0.975 | |
Hospital management support for patient safety (Cronbach α = 0.61) | 2620 | 63.33 | 1445 | 61.83 | 1175 | 65.28 | −2.217 | 0.027 * | |
Hospital management provides a work climate that promotes patient safety. | 766 | 55.50 | 435 | 55.84 | 331 | 55.17 | −0.307 | 0.759 | |
The actions of hospital management show that patient safety is a top priority. | 1017 | 73.70 | 560 | 71.89 | 457 | 76.17 | −2.048 | 0.041 * | |
Hospital management is interested in patient safety only after an adverse event happens. R | 837 | 60.70 | 450 | 57.77 | 387 | 64.50 | −3.201 | 0.001 * | |
Outcome dimensions | Overall perceptions of safety (Cronbach α = 0.87) | 3219 | 58.36 | 1835 | 58.89 | 1384 | 57.67 | 0.002 | 0.998 |
The scenario that extremely serious mistakes do not happen around here is only by chance. R | 968 | 70.20 | 536 | 68.81 | 432 | 72.00 | −2.157 | 0.031 * | |
We had patient safety problems in this unit. R | 471 | 34.20 | 276 | 35.43 | 195 | 32.50 | 0.521 | 0.602 | |
Patient safety is never sacrificed to get considerable work done. R | 979 | 71.00 | 571 | 73.30 | 408 | 68.00 | 1.655 | 0.098 | |
Our procedures and systems are good at preventing errors from happening. | 801 | 58.10 | 452 | 58.02 | 349 | 58.17 | −0.338 | 0.735 | |
Frequency of events reported (Cronbach α = 0.80) | 1357 | 32.80 | 753 | 32.22 b | 604 | 33.56 b | 0.503 | 0.615 | |
When a mistake is made, but is caught and corrected before affecting the patient, how often is this reported? | 487 | 35.30 | 277 | 35.56 | 210 | 35.00 | 0.031 | 0.976 | |
When a mistake is made, but could harm the patient, how often is this reported? | 468 | 33.90 | 247 | 31.71 | 221 | 36.83 | −1.642 | 0.101 | |
When a mistake is made that could harm the patient, but does not, how often is this reported? | 402 | 29.20 | 229 | 29.40 | 173 | 28.83 | 1.371 | 0.171 |
Notes: “a” represents the strength dimensions; “b” represents the weak dimensions; * represents the dimensions and items with statistical significance in surgical departments compared with those in other units; “R” represents the negatively worded items.
Among these 12 safety culture dimensions, the range of PPRs at the hospital level was 32.80–80.29%, that of the surgical departments was between 32.22% and 80.62%, and that of the other departments was from 33.56% to 79.88% (Table 2).
Among the 12 dimensions, those whose PPRs exceeded or equaled 75% were regarded as areas of strength, whereas those whose PPRs were less than or equal to 50% were considered as fields of weakness [33]. Table 2 exhibits that the surgical departments and other units’ strong dimensions included “teamwork within units” as well as “organizational learning and continuous improvement”, and their weak dimensions included “staffing”, “non-punitive response to errors”, as well as “frequency of events reported”.
In the comparison of safety culture between surgical departments and other departments, three dimensions were statistically significant: “non-punitive response to errors” in surgical departments, which was worse than that in other departments (38.68% vs. 40.61%, p = 0.001); “supervisor /manager expectations and actions promoting patient safety” in surgical settings, which was weaker than that in others (69.42% vs. 71.63%, p = 0.013); and surgical settings’ “hospital management support for patient safety”, which was also lower than that in other settings (61.83% vs. 65.28%, p = 0.027). The differences in other safety culture dimensions between two departments had no statistical significance.
Certain patient safety culture items were also considered in the comparison between the two types of departments. The surgical settings showed good performance for the items “Mistakes have led to positive changes here” and “We have enough staff to handle the workload”. The surgical workers agreed strongly with the reversed items “The staff feel like their mistakes are held against them”, “Whenever pressure builds up, my supervisor/manager wants us to work faster, even if it means taking shortcuts”, “Hospital management seems interested in patient safety only after an adverse event happens”, and “The scenario that extremely serious mistakes do not happen around here is only by chance” in comparison with the employees in other units, thereby presenting a weak safety culture in surgical settings. Similarly, the item “The actions of hospital management show that patient safety is a top priority” was also weaker in surgical units than in other units.
3.3. Comparison between Surgical Departments and Other Departments Concerning “Patient Safety Grade” and “Number of Events Reported”
The surgical units and other departments had nearly 50% respondents who believed that the “patient safety grade” of their respective departments was “good”. Moreover, the surgical departments and other departments, respectively, had 7.45% and 10.33% respondents who thought that the “patient safety grade” of their departments was “excellent”. In terms of the “number of events reported”, the surgical departments and other departments, respectively, had 49.94% and 58.84% respondents who did not report adverse events in 2015. In addition, more than 25% of the respondents reported 1–2 adverse events in both departments. Few respondents reported more than 10 cases of adverse events. Table 3 shows the details.
Table 3.
Outcome Variables | Kinds | Surgical Departments (n = 792) | Other Departments (n = 1978) | Pearson X2 |
---|---|---|---|---|
Patient safety grade | Excellent | 58 (7.45%) | 62 (10.33%) | X2 = 11.327 p = 0.010 |
Good | 367 (47.11%) | 301 (50.17%) | ||
Acceptable | 321 (41.20%) | 201 (33.50%) | ||
Poor/failing | 33 (4.24%) | 36 (6.00%) | ||
Number of events reported | No reports | 389 (49.94%) | 353 (58.83%) | X2 = 11.181 p = 0.025 |
1–2 reports | 231 (29.65%) | 150 (25.00%) | ||
3–5 reports | 110 (14.12%) | 65 (10.83%) | ||
6–10 reports | 28 (3.59%) | 17 (2.83%) | ||
>10 reports | 21 (2.70%) | 15 (2.50%) |
Through the X2 test, we found a statistical difference (p = 0.010 and p = 0.025, respectively) in the comparison of “patient safety grade” and “number of events reported” between the surgical units and other departments. Specifically, a small proportion of respondents in surgical departments thought that “patient safety grade” was “excellent/good” compared with that in other departments, but the former had more adverse events reported compared with the latter (Table 3).
3.4. Factors Influencing the “Overall Perception of Safety” and “Frequency of Events Reported” in Surgical Departments
In our study, we used the two-level regression with the staff as the first level and the hospital as the second level. The staff characteristics of Table 1 are the variables of the first level, and the second level takes the first 10 HSOPC dimensions as regression (so it excludes the last two dimensions). The two-level zero model (the regression model is empty, i.e., contains no regression variables) of fitting for “overall perception of safety” in surgical departments showed that ICC = 0.031/(0.031 + 0.377) = 0.076 (p = 0.025), with the overall perception of safety as the dependent variable. The hospital difference makes a contribution of approximately 7.6% to the change in the scores of the overall perception of safety with statistical significance. Accordingly, the overall perception of safety should be analyzed with a two-level model. With regard to the frequency of events reported, ICC = 0.040/(0.040 + 0.876) = 0.044 (p = 0.051), indicating the necessity of multiple linear regression instead of a multiple level model (Table 4).
Table 4.
Overall Perceptions of Safety a | Frequency of Events Reported b | |||||||||||
---|---|---|---|---|---|---|---|---|---|---|---|---|
Fixed Effect Estimation | ||||||||||||
Parameter | Estimate | SE | df | p | 95% CI | Estimate | SE | df | p | 95% CI | ||
Intercept | 3.52 | 0.048 | 17.92 | <0.001 | 3.419 | 3.621 | 3.001 | 0.06 | 18.235 | <0.001 | 2.875 | 3.126 |
Random Effect Estimation | ||||||||||||
Parameter | Estimate | SE | Wald Z | p | 95% CI | Estimate | SE | Wald Z | p | 95% CI | ||
Residual | 0.377 | 0.019 | 19.513 | <0.001 | 0.341 | 0.416 | 0.876 | 0.045 | 19.527 | <0.001 | 0.792 | 0.969 |
Intercept (subject = hospital) | 0.031 | 0.014 | 2.245 | 0.025 | 0.013 | 0.073 | 0.04 | 0.021 | 1.955 | 0.051 | 0.015 | 0.110 |
Notes: a Dependent variable: Overall perceptions of safety; b Dependent variable: Frequency of events reported.
The results based on the two-level linear regression model verified that only the staff characteristic “Staff position” exerted an influence on the dimension “overall perceptions of safety”. Furthermore, six dimensions (“teamwork within units”, “organizational learning and continuous improvement”, “staffing”, “non-punitive response to errors”, “supervisor/manager expectations and actions promoting patient safety”, and “hospital management support for patient safety”) affected “overall perceptions of safety” with statistical significance. All these six dimensions had a positive correlation with the dimension “overall perceptions of safety” (Table 5).
Table 5.
Parameter | Overall Perception of Safety a(n = 1379) | Frequency of Events Reported b(n = 1379) | Collinearity | |||||||
---|---|---|---|---|---|---|---|---|---|---|
Estimate | p | 95% CI | Estimate | p | 95% CI | |||||
Lower | Upper | Lower | Upper | Tolerance | VIF c | |||||
Intercept | 0.082 | 0.742 | −0.409 | 0.574 | 1.186 | 0.006 | 0.343 | 2.029 | ||
Staff position | 0.089 | 0.037 * | 0.006 | 0.172 | 0.012 | 0.868 | −0.133 | 0.158 | 0.760 | 1.316 |
Years in hospital | −0.027 | 0.285 | −0.076 | 0.022 | 0.087 | 0.048 * | 0.001 | 0.174 | 0.218 | 4.594 |
Years in department | −0.024 | 0.365 | −0.077 | 0.028 | −0.047 | 0.319 | −0.140 | 0.046 | 0.220 | 4.546 |
Years in current profession | 0.006 | 0.778 | −0.038 | 0.051 | −0.013 | 0.745 | −0.091 | 0.065 | 0.438 | 2.284 |
Hours worked per week | 0.027 | 0.201 | −0.014 | 0.068 | 0.053 | 0.148 | −0.019 | 0.124 | 0.848 | 1.180 |
Average monthly income | 0.010 | 0.761 | −0.057 | 0.077 | 0.083 | 0.149 | −0.030 | 0.195 | 0.843 | 1.187 |
Contact with patients | 0.136 | 0.144 | −0.047 | 0.319 | 0.109 | 0.503 | −0.211 | 0.430 | 0.939 | 1.065 |
Teamwork within units | 0.169 | <0.001 * | 0.089 | 0.249 | 0.016 | 0.826 | −0.123 | 0.154 | 0.545 | 1.834 |
Organizational learning and continuous improvement | 0.147 | <0.001 * | 0.067 | 0.226 | 0.117 | 0.100 | −0.023 | 0.257 | 0.582 | 1.717 |
Staffing | 0.144 | <0.001 * | 0.067 | 0.220 | −0.046 | 0.492 | −0.179 | 0.086 | 0.859 | 1.164 |
Nonpunitive response to error | 0.095 | 0.001 * | 0.041 | 0.149 | −0.006 | 0.903 | −0.101 | 0.089 | 0.754 | 1.327 |
Supervisor/manager expectations and actions promoting patient safety | 0.179 | <0.001 * | 0.100 | 0.258 | 0.043 | 0.541 | −0.095 | 0.181 | 0.510 | 1.960 |
Feedback and communication about errors | 0.027 | 0.415 | −0.038 | 0.091 | 0.469 | 0.000 * | 0.356 | 0.581 | 0.528 | 1.893 |
Communication openness | −0.029 | 0.423 | −0.099 | 0.041 | −0.104 | 0.098 | −0.227 | 0.019 | 0.573 | 1.746 |
Hospital handoffs and transitions | 0.009 | 0.789 | −0.058 | 0.077 | 0.022 | 0.718 | −0.096 | 0.139 | 0.575 | 1.739 |
Teamwork across hospital units | 0.066 | 0.125 | −0.019 | 0.151 | 0.267 | 0.000 * | 0.118 | 0.415 | 0.438 | 2.282 |
Hospital management support for patient safety | 0.067 | 0.037 * | 0.004 | 0.131 | 0.087 | 0.117 | −0.022 | 0.196 | 0.502 | 1.991 |
Notes: * represents the dimensions and items with statistical significance in surgical departments; a Two-level multiple linear regression model: the first level comprises medical staff in surgical units, and the second level comprises county hospitals; b Multiple linear regression model; c VIF: Variance inflation factor. All VIFs < 5, showing no collinearity among the independent variables.
In terms of “frequency of events reported” based on multiple linear regression, only “years in hospital” was the influencing factor. Only two dimensions, namely, “feedback and communication about errors” and “teamwork across hospital units” exerted an influence on the “frequency of events reported”. When the results of the two dimensions are satisfactory, the “frequency of events reported” is also satisfactory (Table 5).
3.5. Factors Affecting “Patient Safety Grade” and “Number of Events Reported” in Surgical Departments
Similar to the previous two-level analysis, the fitting zero model of “patient safety grade” and “number of events reported” in surgical departments indicated that the variation of both outcome variables had statistical significance (p < 0.05) in the hospital level (Table 6). Therefore, “patient safety grade” and “number of events reported” should be analyzed with a two-level model with consideration of the clustering effect of hospital medical staff within hospitals. As categorical variables, the models should be carried out as two-level ordered logistic regression models.
Table 6.
Estimate | SE | Z | p > |Z| | (95% Conf. Interval) | ||
---|---|---|---|---|---|---|
Patient Safety Grade | ||||||
Excellent | −2.614 | 0.177 | −14.800 | <0.001 | −2.960 | −2.268 |
Good | 0.152 | 0.132 | 1.150 | 0.250 | −1107.000 | 0.410 |
Acceptable | 3.168 | 0.211 | 15.010 | <0.001 | 2.754 | 3.582 |
Poor/failing | 5.099 | 0.463 | 11.020 | <0.001 | 4.192 | 6.007 |
Hospital Var(_cons) | 0.197 | 0.109 | 0.066 | 0.583 | ||
LR test vs. ologit model: chibar2(01) = 11.88, Prob ≥ chibar2 = 0.0003 | ||||||
Number of Events Reported | ||||||
No events | 0.105 | 0.160 | 0.650 | 0.513 | −0.209 | 0.418 |
1–2 Events | 1.583 | 0.171 | 9.260 | <0.001 | 1.248 | 1.918 |
3–5 Events | 3.001 | 0.212 | 14.140 | <0.001 | 2.585 | 3.417 |
6–10 Events | 3.854 | 0.270 | 14.270 | <0.001 | 3.325 | 4.383 |
>10 Events | 5.081 | 0.435 | 11.670 | <0.001 | 4.228 | 5.935 |
Hospital Var(_cons) | 0.336 | 0.150 | 0.140 | 0.806 | ||
LR test vs. ologit model: chibar2(01) = 48.51, Prob ≥ chibar2 = 0.0001 |
Notes: LR test is conservative and provided only for reference; Pro ≥ chibar2 equals to p value.
Table 7 shows that medical staff in surgical units with hospital work experience of 1–5 years or 16–20 years gave lower patient safety grade than those with less than 1 year of experience in county hospitals. Health workers in surgical settings with 1–5 years, 6–10 years, and 11–15 years of experience gave a higher patient safety grade than those with <1 year of experience in the position. Moreover, the good results of the dimensions “organizational learning and continuous improvement”, “supervisor/manager expectations and actions promoting patient safety”, “feedback and communication about errors”, and “hospital handoffs and transitions” of the respondents equated to a good “patient safety grade”.
Table 7.
Threshold | PSG Reference Category: PSG = Excellent | NER Reference Category: NER = “>10 Events” | |||||||
---|---|---|---|---|---|---|---|---|---|
Estimate | p | 95% CI | Estimate | p | 95% CI | ||||
PSG = good | −10.433 | <0.001 | −12.648 | −8.218 | NER = no events | −0.265 | 0.801 | −2.325 | 1.795 |
PSG = acceptable | −7.185 | <0.001 | −9.323 | −5.048 | NER = 1–2 events | 1.363 | 0.195 | −0.697 | 3.423 |
PSG = poor/failing | −3.672 | 0.001 | −5.774 | −1.571 | NER = 3–5 events | 2.880 | 0.006 | 0.806 | 4.954 |
NER = 6–10 events | 3.760 | <0.001 | 1.658 | 5.861 | |||||
Staff Position | |||||||||
Physician | 0 a | 0 a | |||||||
Nurse | 0.071 | 0.761 | −0.281 | 0.423 | −0.409 | 0.024 * | −0.763 | −0.054 | |
Years in Hospital | |||||||||
<1 year | 0 a | 0 a | |||||||
1–5 years | −0.140 | 0.761 | −1.039 | 0.760 | 1.031 | 0.030 * | 0.101 | 1.960 | |
6–10 years | −0.601 | 0.258 | −1.642 | 0.441 | 1.586 | 0.003 * | 0.525 | 2.648 | |
11–15 years | −0.321 | 0.601 | −1.525 | 0.883 | 2.033 | 0.001 * | 0.801 | 3.264 | |
16–20 years | 0.011 | 0.986 | −1.218 | 1.240 | 2.320 | <0.001 * | 1.066 | 3.573 | |
>21 years | −0.282 | 0.656 | −1.526 | 0.961 | 2.691 | <0.001 * | 1.450 | 3.931 | |
Years in Department | |||||||||
<1 year | 0 a | 0 a | |||||||
1–5 years | −0.702 | 0.047 * | −1.393 | −0.010 | −0.106 | 0.762 | −0.796 | 0.583 | |
6–10 years | −0.597 | 0.199 | −1.508 | 0.314 | −0.825 | 0.074 | −1.729 | 0.080 | |
11–15 years | −0.056 | 0.918 | −1.120 | 1.008 | −0.639 | 0.235 | −1.694 | 0.416 | |
16–20 years | −1.161 | 0.046 * | −2.300 | −0.021 | −1.068 | 0.063 | −2.194 | 0.058 | |
>21 years | −0.202 | 0.740 | −1.392 | 0.989 | −0.912 | 0.122 | −2.067 | 0.243 | |
Years in Current Profession | |||||||||
<1 year | 0 a | 0 a | |||||||
1–5 years | 1.181 | 0.004 * | 0.372 | 1.989 | −0.189 | 0.645 | −0.992 | 0.614 | |
6–10 years | 1.307 | 0.006 * | 0.378 | 2.235 | 0.317 | 0.495 | −0.595 | 1.230 | |
11–15 years | 1.122 | 0.029 * | 0.112 | 2.133 | −0.057 | 0.910 | −1.046 | 0.931 | |
16–20 years | 1.006 | 0.068 | −0.074 | 2.087 | −0.234 | 0.671 | −1.312 | 0.844 | |
>21 years | 1.043 | 0.096 | −0.184 | 2.270 | −0.545 | 0.378 | −1.756 | 0.667 | |
Hours Worked per Week | |||||||||
<20 h | 0 a | 0 a | |||||||
20–39 h | 0.043 | 0.949 | −1.276 | 1.363 | −0.759 | 0.231 | −2.000 | 0.482 | |
40–59 h | 0.156 | 0.811 | −1.124 | 1.436 | −0.934 | 0.128 | −2.136 | 0.268 | |
60–79 h | 0.147 | 0.828 | −1.176 | 1.469 | −0.827 | 0.191 | −2.065 | 0.412 | |
80–99 h | 0.136 | 0.851 | −1.289 | 1.562 | −1.812 | 0.009 * | −3.173 | −0.451 | |
>100 h | −0.184 | 0.809 | −1.676 | 1.308 | −0.910 | 0.206 | −2.320 | 0.500 | |
Average Monthly Income | |||||||||
<3000 RMB | 0 a | 0 a | |||||||
3000–5000 RMB | 0.118 | 0.507 | −0.231 | 0.467 | 0.173 | 0.318 | −0.166 | 0.512 | |
5000–8000 RMB | 0.322 | 0.414 | −0.451 | 1.095 | −0.061 | 0.866 | −0.770 | 0.647 | |
>8000 RMB | −1.382 | 0.224 | −3.609 | 0.845 | −21.124 | 0.999 | −41.25 | −10.237 | |
Contact with Patients | |||||||||
Yes | 0 a | 0 a | |||||||
No | 0.176 | 0.668 | −0.627 | 0.978 | −0.014 | 0.972 | −0.818 | 0.790 | |
Teamwork within units | −0.081 | 0.630 | −0.412 | 0.249 | −0.195 | 0.241 | −0.520 | 0.131 | |
Organizational learning and continuous improvement | 0.489 | 0.004 * | 0.152 | 0.826 | 0.022 | 0.896 | −0.305 | 0.349 | |
Staffing | 0.104 | 0.522 | −0.214 | 0.422 | 0.079 | 0.620 | −0.234 | 0.392 | |
Nonpunitive response to error | −0.173 | 0.134 | −0.400 | 0.053 | 0.092 | 0.420 | −0.132 | 0.317 | |
Supervisor/manager expectations and actions promoting patient safety | 0.368 | 0.031 * | 0.034 | 0.703 | 0.147 | 0.373 | −0.177 | 0.472 | |
Feedback and communication about errors | 0.347 | 0.012 * | 0.076 | 0.618 | 0.240 | 0.080 | −0.028 | 0.509 | |
Communication openness | 0.083 | 0.577 | −0.209 | 0.375 | 0.095 | 0.516 | −0.191 | 0.381 | |
Hospital handoffs and transitions | 0.477 | 0.002 * | 0.171 | 0.782 | 0.418 | 0.003 * | 0.142 | 0.695 | |
Teamwork across hospital units | −0.175 | 0.343 | −0.537 | 0.187 | −0.173 | 0.328 | −0.519 | 0.174 | |
Hospital management support for patient safety | −0.168 | 0.220 | −0.435 | 0.100 | 0.079 | 0.557 | −0.184 | 0.341 |
Notes: Join function: Logit. a This parameter is set to 0 because it is redundant. CI: confidence interval, PSG: patient safety grade, NER: number of events reported. * represents the dimensions and items with statistical significance in surgical departments. PSG: Patient safety grade. NER: Number of events reported.
With regard to the “number of events reported”, the nurses reported fewer adverse events than the doctors in surgical departments. The staff with tenure of “1–5 years”, “6–10 years”, “11–15 years”, and “>20 years” in the hospital reported more adverse events than the staff with “<1 year” of tenure in surgical settings of county hospitals. The surgical staff working in their unit 80–90 h per week reported fewer adverse events than those working <20 h per week. Respondents who had low scores on “hospital handoff and transition” reported several adverse events (Table 7).
4. Discussion
Our research is one of the few studies on the comparison of patient safety culture among different departments in hospitals. In China, this study is the first attempt to explore safety culture issues in surgical departments compared with those in other departments in county hospitals. This study will help test the application of the HSOPSC in China to provide a reference for the safety culture assessment of Chinese county hospitals.
Our study highlighted the advantages of the dimensions “teamwork within units” and “organizational learning and continuous improvement” in surgical settings. Without considering the economic level and hospital effects, we found this result to be different from those of the dimensions with the top two highest PPRs from non-surgical departments of nursing homes [34] and neonatal intensive units [17] although the results are similar to the strength dimensions of surgical units in other regions [26]. Evidently, China can learn from the measures and strategies of the safety culture construction of surgical departments in foreign hospitals to improve the safety culture of surgical departments in county hospitals. Furthermore, the differences of the items showed that the staff in surgical units held better perceptions of “Mistakes have led to positive changes here” and “We have enough staff to handle the workload” than those in other settings. In addition, the proportion of medical staff who reported events was larger in surgical units than in other departments. These findings represent the aspects of county hospitals that should be continuously consolidated.
In this study, certain dimensions were found to have an effect on the outcome dimensions. Six dimensions had a positive influence on the “overall perceptions of safety”, and two dimensions had a good effect on the “frequency of events reported”. Moreover, the dimension “hospital handoffs and transitions” was related to “patient safety grade” and “number of events reported”. The high scores of the former dimension equated to a good “patient safety grade” and “number of events reported”. Therefore, by improving the factors that can affect outcome dimensions and categorical outcomes, such as continuing to strengthen the teamwork within or outside surgical units and organizational learning as well as ensuring good feedback and communication as well as hospital handoffs and transitions, we can indirectly improve the overall safety level of hospitals [26].
Although surgical settings presented their own characteristics and advantages, our study found certain weak dimensions that require improvement. These dimensions included “staffing”, “non-punitive response to errors”, and “frequency of events reported”. In addition, the dimensions “supervisor/manager expectations and actions promoting patient safety” and “hospital management support for patient safety” in surgical settings were lower than those in other settings. Certain items were also much weaker in surgical settings than in others. These items included “The staff feel like their mistakes are held against them”, “Whenever pressure builds up, my supervisor/manager wants us to work faster, even if it means taking shortcuts”, and “Hospital management seems interested in patient safety only after an adverse event happens”, “The scenario that extremely serious mistakes do not happen around is only by chance”, and “The actions of hospital management show that patient safety is a top priority”. In the following paragraphs, we will discuss how to improve the weak dimensions and items.
In the results, “staffing” received the lowest PPRs in surgical settings and others. Accordingly, staffing is the most serious problem concerning patient safety culture. Hellings [35] and Smits [36] also found the same issue. Although the respondents felt good about “whether the surgical units have enough staff to handle the workload”, county hospitals still suffer from the lack of health personnel [37]. Surgical staff face a heavy workload, with nearly 85% of them working more than 40 h per week and more than 25% of them working more than 60 h per week. The large amount of work overload not only leads to mental and physical exhaustion for medical personnel but also results in the emergence of anxiety, depression, and other health problems, all of which may increase the adverse event incidence and are not conducive to patient health [38]. In our study, “staffing” had a positive influence on “overall perceptions of safety”. Consequently, the number of medical staff in Chinese county hospitals should be increased [39]. Meanwhile, it is also important to clear division of labor to ease the workload of medical staff.
The dimension “non-punitive response to errors” showed the second lowest PPRs. Similar to our study, other works found low PPRs for the dimension “non-punitive response to errors” [40,41]. On the one hand, the medical staff may worry that their mistakes will be included in their personal files and that reporting errors may lead to their suffering punishment, although hospitals stipulate no punishment for reported errors. On the other hand, Chinese medical workers may hold a wrong view that the number of adverse events reported shows their poor ability, which may affect their honor and income. This study also corroborated that approximately half of the medical staff in surgical departments and other units had never reported adverse events. The employees’ negligence in reporting adverse events results in the masking of errors, which leads to a vicious cycle of error occurrence. In addition, once the error is not corrected, it may bring serious harm to patients as well as adversely affect the quality and brand of medical service institutions. Evans [42] asserted that a punitive response to errors is a barrier for doctors and nurses to report adverse events. We also elucidated that “non-punitive response to errors” had a positive influence on the “overall perceptions of safety”. Therefore, as “To Err Is Human: Building a Safer Health System” by the IOM pointed out, hospitals should consider abolishing potential rules and regulations on punitive responses for minor medical errors while establishing a mandatory reporting system for those major errors [4]. Only by creating a non-punitive inclusive and open environment can hospitals’ non-punitive culture improve.
The dimensions “supervisor/manager expectations and actions promoting patient safety” and “hospital management support for patient safety”, which were weaker in surgical units than in other units, were also necessary for us to consider. In our study, a small proportion of respondents thought that “The actions of hospital management show that patient safety is a top priority”. They also agreed that “whenever pressure builds up, my supervisor/manager wants us to work faster, even if it means taking shortcuts” and that “hospital management seems interested in patient safety only after an adverse event happens”. Our study is slightly similar to that of Liu [22]. Compared with other units, the surgical units are focused on solving surgical questions instead of considering safety culture building. In the county hospitals of China, supervisors/managers may lack health management basis because they work as surgical doctors at the same time. Supervisors/managers bear a heavy workload that they might have no time to implement management practices, leading to the neglect of patient safety culture. Furthermore, after finishing their work, supervisors/managers may go home or rest, thereby making their communication with employees insufficient. In this case, the staff’s suggestions about safety culture might not be considered by supervisors/managers completely.
Supervisors/managers play an important role in helping their teams establish a culture that offers quality patient care in a safe environment [43]. Furthermore, good leadership is an incentive to improve communication and enhance safety [44]. Among the incentive mechanisms, supervisors/managers’ support and action on employees could prompt the positive work of the latter group. Our study also verified that the support, attitudes, and actions of managers/supervisors toward safety culture in county hospitals did contribute to the overall perception of safety of the respondents and patient safety grade. Consequently, we think that hospital management training could be strengthened to improve the management and consciousness level in surgical units. Similarly, communication with one another may also be advocated to construct a good safety culture in surgical departments [45].
Limitations
Our study has some limitations. First, the some Cronbach alpha values were low (ranging from 0.31 to 0.87). The reason behind the low Cronbach alpha values could possibly be due to the cultural differences between China and other countries. However, we decided not to delete the dimensions with low internal consistency to compare our results with those of other studies. Second, we compared patient safety culture between surgical units and other units for the results, conclusions, and strategies to be suitable for surgical units in county hospitals and not for other units in other hospitals. In other words, our study has the standard limitation of generalizability. Third, because of the limited sample size, the differences between the two kinds of unit groups are relatively small even if they are statistically significant. Fourth, our present study is similar to our previous study [26], especially on the structure. The previous study [26] has provided a reference for our present study. However, there are still some differences between our research and [26]: (1) The subject and sample size are different. We studied the safety culture of 19 hospitals, while the [26] studied the safety culture of only one tertiary hospital. (2) The method was not completely the same. We used the multilevel statistical method, which was not used by [26]. (3) The content is not all the same. Our study not only compared the 12 dimensions of patient safety culture between surgical and non-surgical departments, but also compared the differences between the 42 items. However, the [26] just compared the 12 dimensions between the two groups. (4) The results were different. The strengths and weaknesses of the patient safety culture in the surgical units of the county hospitals are not all the same as those of the tertiary hospital. Meanwhile, the county hospitals emphasized the management on patient safety culture, which was not mentioned by the former study. (5) Our research strategy proposed according to the research results is not exactly the same as the [26]. Despite these limitations, our methods, results, and strategies may be helpful for those county hospitals willing to assess and improve their patient safety culture.
5. Conclusions
Much can be done in the context of county hospitals to improve patient safety in surgical departments. Recruiting workers, using the reporting system as frequently as possible, and building a non-punitive culture were recommended to ensure patient safety. In addition, supervisors should also attach priority to patient safety and play a key role in promoting the culture.
Acknowledgments
We would like to thank all the respondents for participating in the survey. We are grateful to the doctors and nurses for their efforts in the coordination of the field work. We also thank the staff of the Affiliated Hospital of Jining Medical University in China for their willingness to take part in the pre-survey. We are grateful to the National Health and Family Planning Commission of the People’s Republic of China for funding of this research (grant number 20131577).
Abbreviations
CI | confidence interval |
HSOPSC | Hospital Survey on Patient Safety Culture |
PPRs | percent positive ratings |
AHRQ | Agency of Healthcare Research and Quality |
RMB | Ren Min Bin |
PSG | patient safety grade |
NER | number of events reported |
Author Contributions
Hongbing Tao contributed to the conception and design of the project. Manli Wang contributed to the analysis and interpretation of the data. Manli Wang contributed to the data acquisition and provided statistical analysis support. Manli Wang and Hongbing Tao drafted the article. Other authors took part in the revision of the manuscript. All the authors participated in the investigation and interviews.
Conflicts of Interest
The authors declare no conflict of interest.
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