Implementing an Antimicrobial Stewardship Programme to Improve Adherence to a Perioperative Prophylaxis Guideline

Nehad J Ahmed; Ziyad S Almalki; Abdullah A Alfaifi; Ahmed M Alshehri; Abdullah K Alahmari; Emad Elazab; Alaa Almansour; Abdul Haseeb; Mohamed F Balaha; Amer H Khan

doi:10.3390/healthcare10030464

. 2022 Mar 1;10(3):464. doi: 10.3390/healthcare10030464

Implementing an Antimicrobial Stewardship Programme to Improve Adherence to a Perioperative Prophylaxis Guideline

Nehad J Ahmed ^1,², Ziyad S Almalki ¹, Abdullah A Alfaifi ¹, Ahmed M Alshehri ¹, Abdullah K Alahmari ¹, Emad Elazab ³, Alaa Almansour ⁴, Abdul Haseeb ⁵, Mohamed F Balaha ^1,⁶, Amer H Khan ^2,^*

Editor: Farhad Kamali

PMCID: PMC8953150 PMID: 35326942

Abstract

Perioperative antimicrobial prophylaxis is effective in reducing the rate of surgical site infections (SSIs); however, non-adherence to surgical antimicrobial prophylaxis protocols can lead to several negative outcomes. We performed a before-and-after intervention study with the aim of improving the process outcome, including adherence to guidelines. Another objective of this study was to investigate improvement in patient outcomes as a result of adherence to a surgical antimicrobial prophylaxis programme. The indicators of improved patient outcomes were a reduction in overall SSI rate and the decreased cost of antibiotics. SSI rate was calculated as a percentage by dividing the number of SSIs by the total number of surgeries and then multiplying the value obtained by 100%. The interventions implemented in the surgical antimicrobial prophylaxis programme included establishment of a guideline, educational sessions, and a monthly revision of prescriptions. Our findings show that implementation of the interventions resulted in reduced antibiotic consumption, a considerable decrease in the cost of prophylaxis, and a decrease in the incidence of SSIs.

Keywords: antimicrobial stewardship, surgical site infection, surgical antimicrobial prophylaxis

1. Introduction

Surgical site infections (SSIs) are the most common healthcare-associated infections that occur among surgical patients. It is reported that SSIs lead to prolonged hospital stay, readmission to the hospital, and increased mortality and morbidity rates [1]. SSIs are defined as postoperative infections that occur within 30 days after undergoing a surgical procedure, or within 1 year after placement of a permanent implant [2]. It is indicated in a European Centre for Disease Prevention and Control report that the cumulative incidence of SSIs mainly depends on the type of surgical procedure; the highest rates have been reported for open colorectal and laparoscopic colorectal operations (10.1% and 6.4%, respectively), followed by open cholecystectomy (3.9%) and coronary artery bypass graft (2.6%) [2]. Studies on SSIs have largely focused on surgeries performed on the gastrointestinal tract, which can result in higher SSI rates compared to other procedures. Among the different types of gastrointestinal surgeries, colorectal surgery is the most concerning regarding the development of SSIs due to the presence of multiple microbes in the colon and rectum [3]. The number of bacteria and proportion of anaerobic bacteria progressively increase along the gastrointestinal tract; therefore, SSIs that develop after gastrointestinal surgeries must be treated based on the sites at which the procedures were performed [4].

Perioperative antimicrobial prophylaxis has been shown to be effective in reducing the rate of SSIs after surgical procedures [5]. However, inappropriate implementation of surgical antimicrobial prophylaxis, in terms of prolonged duration of the prophylactic treatment in addition to the use of broad-spectrum antibiotics, can result in the development of antibiotic resistance as well as high treatment costs [6]. Moreover, inappropriate timing of surgical antimicrobial prophylaxis can lead to a decrease in the efficacy of the prophylaxis [7]. Therefore, the quality of prophylaxis has been the subject of several audits [8,9,10,11,12] and interventional studies [13,14,15,16,17,18,19,20], and numerous national guidelines have been developed to support appropriate implementation of prophylaxis protocols [21,22,23,24].

Antimicrobial stewardship programmes (ASPs) are one of the most important aspects of multipronged interventions to decrease the incidence of SSIs as well as morbidity from antimicrobial-resistant SSIs [25]. The definition for antimicrobial stewardship is an organisational or healthcare system-wide approach to promote and monitor the judicious use of antimicrobials to preserve their future effectiveness [26].

Research on ASP implementation in Saudi Arabia and the effect of antimicrobial stewardship in surgical antibiotic prophylaxis in the region is scarce. To the best of our knowledge, this study is the first to assess the effect of ASP interventions on surgical antimicrobial prophylaxis in Al-Kharj city.

The present study analysed data from various gastrointestinal surgery cases including colorectal surgeries, appendectomies, and bile duct/gall bladder and aimed to investigate the impact of interventions in a surgical antimicrobial prophylaxis programme on process outcome parameters (administration of prophylactic antibiotics) and patient outcome (reduction in SSI rate and cost of consumed antibiotics) at Al-Kharj Military Industries Corporation Hospital (Al-Kharj, Saudi Arabia).

2. Materials and Methods

2.1. Setting

This study was a prospective interventional study performed at Al-Kharj Military Industries Corporation Hospital (Al-Kharj, Saudi Arabia). The management of this hospital is responsible for developing health care facilities as well as creating health awareness and providing medical care to members of the armed forces and their families.

2.2. Data Collection

During the pre- and post-intervention periods, all procedures meeting the inclusion criteria below were included in the analysis. Data were extracted from surgery files and electronic medical records. The data included type of surgery, date of surgery, patient’s age and gender, and the prescribed medications.

The durations of the pre- and post-intervention phases of data collection depended on the number of procedures in each phase; as a result, there were variations in the data for the two phases. Activities for the pre-intervention phase started on 1 June 2019 and ended on 15 December 2019, whereas those for the post-intervention phase started on 16 December 2019 and ended on 30 July 2020. To obtain a balanced distribution of the selected procedures, the number of different gastrointestinal surgeries and the age and gender of patients were almost similar before and after the intervention.

2.3. Inclusion and Exclusion Criteria

The data on all colorectal surgeries, appendectomies, and bile duct/gall bladder surgeries that were performed during the study period were included in the analysis. Other types of surgeries and surgeries that were conducted before or after the study period were excluded from the analysis.

2.4. Interventions

A guideline on surgical antimicrobial prophylaxis was established, after which implementation of the interventions in the guideline was evaluated. The antibiotic use committee in the hospital announced the guideline to the clinical staff and after that several educational sessions were organized by physicians in the hospital and by an academic staff in the clinical pharmacy department at Prince Sattam Bin Abdulaziz university on antimicrobial stewardship and about the correct use of antibiotics as recommended in surgical antimicrobial prophylaxis guidelines. In addition, monthly reviews of prescribing patterns in the surgery department were conducted to assess improvement in the prescription of antibiotics, with respect to appropriateness of antibiotic selection, route of drug administration, timing of drug administration, antibiotic dose(s), and duration of prophylaxis and after that, feedback was sent to the surgeons.

2.5. Data Analysis

The main objectives of this study were to assess improvements in process and patient outcomes as a result of adherence to the guideline and implementation of the recommended protocols. The aim of the surgical antimicrobial prophylaxis programme was to reduce the overall SSI rate and decrease the cost of consumed antibiotics among patients. SSI rate was calculated as a percentage (%) by dividing the number of SSIs by the total number of surgeries and multiplying the value obtained by 100%.

Antimicrobial use was analysed quantitatively by calculating the defined daily dose (DDD) per 100 procedures. DDDs were obtained from the ATC/DDD Index 2003 of the World Health Organization Collaborating Centre for Drug Statistics Methodology [27]. The cost of consumed antibiotics was calculated by multiplying the DDD/100 surgeries by the cost of the antibiotics. Courses of antimicrobial drugs were reviewed for drug choice, administration route, dosage, and duration and timing of prophylaxis. If no antibiotic prescriptions were recorded, it was assumed that antibiotics had not been administered. All the results have been presented as numbers and percentages. The data were evaluated with the F-test, then were compared with either the two-sample Student’s t-test or the Mann–Whitney’s U test.

3. Results

3.1. Patients’ Characteristics

Table 1 shows the number and percentages of gastrointestinal surgeries that were included in the study with respect to the age ranges and gender of the patients. The number of surgeries before implementation of the guideline was 178; however, 184 surgeries were recorded after implementation of the guideline. More than half of the patients were female, and the majority of them were aged 20–49 years in both the pre- and post-intervention phases.

Table 1.

Patients who underwent gastrointestinal surgery before and after the intervention.

Variable	Category	Number of Patients in the Pre-Intervention Phase n (%)	Number of Patients in the Post-Intervention Phase n (%)
Gender	Male	85 (47.75)	86 (46.74)
Gender	Female	93 (52.25)	98 (53.26)
Age (years)	<10	8 (4.49)	10 (5.43)
	10–19	29 (16.29)	29 (15.76)
	20–29	37 (20.79)	39 (21.20)
	30–39	48 (26.97)	44 (23.92)
	40–49	30 (16.86)	38 (20.65)
	50–59	19 (10.67)	15 (8.15)
	>59	7 (3.93)	9 (4.89)

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Table 2 shows the specific number and percentages of bile and gall bladder surgeries, colorectal surgeries, and appendectomies included in the study. The most performed surgeries in the pre-intervention phase were bile duct/gall bladder surgeries (46.07%), followed by appendectomies (39.33%) and colorectal surgeries (14.60%). The most performed gastrointestinal surgeries in the post-intervention phase were appendectomies (42.93%), followed by bile duct/gall bladder surgeries (41.31%) and colorectal surgeries (15.76%).

Table 2.

Surgeries performed on the patients.

Type of Surgery	Number of Surgeries in the Pre-Intervention Phase n (%)	Number of Surgeries in the Post-Intervention Phase n (%)
Appendectomy	70 (39.33)	79 (42.93)
Bile duct/Gall bladder surgery	82 (46.07)	76 (41.31)
Colorectal surgery	26 (14.60)	29 (15.76)
Total	178	184

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3.2. Appropriateness of Antimicrobials Used for Prophylaxis

Table 3 shows the frequency at which patients were administered antibiotics. The data show that for all of the included surgeries, patients had to be administered antibiotics. Additionally, antibiotics were not prescribed for the prophylaxis of infections in about 8.99% of surgeries before the intervention and in about 10.87% of surgeries after the intervention.

Table 3.

Frequency of antibiotic use for gastrointestinal surgeries during the pre- and post-intervention phases.

Surgery Type	Use of Antibiotic	Pre-Intervention Phase n (%)	Post-Intervention Phase n (%)
Appendectomy	Yes	68 (97.14)	71 (89.87)
Appendectomy	No	2 (2.86)	8 (10.13)
Bile duct/Gallbladder surgery	Yes	72 (87.80)	68 (89.47)
Bile duct/Gallbladder surgery	No	10 (12.20)	8 (10.53)
Colorectal surgery	Yes	22 (84.62)	25 (86.21)
Colorectal surgery	No	4 (15.38)	4 (13.79)
All gastrointestinal surgeries	Yes	162 (91.01)	164 (89.13)
All gastrointestinal surgeries	No	16 (8.99)	20 (10.87)

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As shown in Table 4, implementation of the surgical antimicrobial prophylaxis programme resulted in improvement in correct antibiotic use. In addition, there were improvements in the prescription of appropriate antibiotic doses, timing of prophylaxis, choice of route of drug administration, and duration of prophylaxis. The appropriateness of drug selection increased from 51.23% before the intervention to 53.05% after the intervention. Appropriateness of drug dose also improved from 32.72% before the intervention to 53.66% after the intervention. The appropriateness of timing increased from 64.81% before implementation of the intervention to 74.39% after the intervention. Similarly, the appropriateness of route of drug administration and duration of prophylaxis improved from 66.67% to 76.83% and from 14.20% to 19.51%, respectively.

Table 4.

Appropriateness of surgical antimicrobial prophylaxis in the pre- and post-intervention phases.

Surgery Type	Appropriateness of Surgical Antimicrobial Prophylaxis		Pre-Intervention Phase n (%)	Post-Intervention Phase n (%)	p-Value
Appendectomy	Selected drug(s)	Appropriate	22 (32.35)	29 (40.85)	0.049
	Selected drug(s)	Inappropriate	46 (67.65)	42 (59.15)
	Drug dose(s)	Appropriate	20 (29.41)	29 (40.85)
	Drug dose(s)	Inappropriate	48 (70.59)	42 (59.15)
	Timing	Appropriate	44 (64.71)	55 (77.46)
	Timing	Inappropriate	24 (35.29)	16 (22.54)
	Route of drug administration	Appropriate	47 (69.12)	57 (80.28)
	Route of drug administration	Inappropriate	21 (30.88)	14 (19.72)
	Duration	Appropriate	2 (2.94)	5 (7.04)
	Duration	Inappropriate	66 (97.06)	66 (92.96)
Bile duct/Gall bladder surgery	Selected drug(s)	Appropriate	55 (76.39)	48 (70.59)	0.461
	Selected drug(s)	Inappropriate	17 (23.61)	20 (29.41)
	Drug dose(s)	Appropriate	24 (37.50)	38 (55.88)
	Drug dose(s)	Inappropriate	48 (62.50)	30 (44.12)
	Timing	Appropriate	46 (63.89)	45 (66.18)
	Timing	Inappropriate	26 (36.11)	23 (33.82)
	Route of drug administration	Appropriate	46 (63.89)	46 (67.65)
	Route of drug administration	Inappropriate	26 (36.11)	22 (32.35)
	Duration	Appropriate	16 (22.22)	21 (30.88)
	Duration	Inappropriate	56 (77.78)	47 (69.12)
Colorectal surgery	Selected drug(s)	Appropriate	6 (27.27)	10 (40.00)	0.0153
	Selected drug(s)	Inappropriate	16 (72.73)	15 (60.00)
	Drug dose(s)	Appropriate	9 (40.91)	21 (84.00)
	Drug dose(s)	Inappropriate	13 (50.09)	4 (16.00)
	Timing	Appropriate	15 (68.18)	22 (88.00)
	Timing	Inappropriate	7 (31.82)	3 (12.00)
	Route of drug administration	Appropriate	15 (68.18)	23 (92.00)
	Route of drug administration	Inappropriate	7 (31.82)	2 (8.00)
	Duration	Appropriate	5 (22.73)	6 (24.00)
		Inappropriate	17 (77.27)	19 (76.00)
		Inappropriate	139 (85.80)	132 (80.49)

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3.3. Reduction in SSI Rate

Table 5 shows the rate of SSIs in 2019 before implementation of the intervention, and in 2020 after implementation of the intervention. The total rate of SSIs in 2019 was 0.41%, whereas that in 2020 was 0.04% (this percentage was for the total rate of SSIs from all surgeries and not for gastrointestinal surgeries only).

Table 5.

Number of SSIs recorded in 2019 and 2020.

Months	SSIs in 2019 (Pre-Intervention Period)		SSIs in 2020 (Post-Intervention Period)
Months	Number of SSIs/Total Number of Surgeries	SSI Rate	Number of SSIs/Total Number of Surgeries	SSI Rate
January–March	3/635	0.47%	0/666	0.00%
April–June	2/639	0.31%	0/469	0.00%
July–September	3/610	0.49%	1/550	0.18%
October–December	3/811	0.37%	0/706	0.00%
Total	11/2695	0.41%	1/2391	0.04%

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3.4. Antimicrobial Use

According to the guideline, the first drug of choice for bile duct and gall bladder surgeries is cefazolin (the recommended antibiotic); however, if cefazolin is not available, cefuroxime or ceftriaxone (alternative agents) may be used. For colorectal surgeries and appendectomy, patients must be administered cefazolin and metronidazole (the recommended combination); however, if cefazolin is not available, cefuroxime or ceftriaxone and metronidazole (alternative agents) may be used. As shown in Table 6, in the post-intervention phase, the use of intravenous cefazolin increased (from 0 to 7.97 DDD/100 surgeries), whereas the use of intravenous cefuroxime decreased (from 13.76 to 0.27 DDD/100 surgeries). Moreover, the use of intravenous metronidazole increased (from 23.31 to 29.07 DDD/100 surgeries), whereas the total consumption of antibiotics reduced from 920.36 to 788.56 DDD/100 surgeries.

Table 6.

Number of patients who were administered different antibiotics before and after the intervention.

Antibiotic	Route of Drug Administration	DDD of Antibiotic before the Intervention	DDD/100 Surgeries before the Intervention	DDD of Antibiotic after the Intervention	DDD/100 Surgeries after the Intervention
Ceftriaxone	Intravenous	1.50	0.84	1	0.54
Cefuroxime	Intravenous	24.5	13.76	0.50	0.27
Cefuroxime	Oral	1414	794.38	994	540.22
Metronidazole	Intravenous	41.50	23.31	53.50	29.07
Metronidazole	Oral	71.4	40.11	63	34.24
Ciprofloxacin	Intravenous	2.25	1.26	0.25	0.14
Ciprofloxacin	Oral	1	0.56	47.50	25.82
Amoxicillin/Clavulanic acid	Oral	62.12	34.90	232.53	126.38
Cefazolin	Intravenous	0	0	14.67	7.97
Doxycycline	Oral	0	0	42	22.83
Trimethoprim/Sulfamethoxazole	Oral	0	0	2	1.09
Cefprozil	Oral	20	11.24	0	0
Total		1638.27	920.36	1450.95	788.56

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As shown in Table 7, the costs of cefuroxime, ceftriaxone, and metronidazole decreased after the intervention, whereas those of ciprofloxacin, Amoxicillin/Clavulanic acid, and cefazolin increased. The maximum estimation of reduction in cost between the pre- and post-intervention phases was 1783.81 Saudi Riyal (9513.92–7730.11) that is equal to 475.39 United States Dollar (p-value < 0.05).

Table 7.

Antibiotic cost before and after the intervention.

Antibiotics	Route of Drug Administration	DDD/100 Surgeries before the Intervention	Antibiotic Cost in the Pre-Intervention Phase	DDD/100 Surgeries after the Intervention	Antibiotic Cost in the Post-Intervention Phase
Ceftriaxone	Intravenous	0.84	77.28	0.54	49.68
Cefuroxime	Intravenous	13.76	598.42	0.27	11.74
Cefuroxime	Oral	794.38	6156.45	540.22	4186.71
Metronidazole	Intravenous	23.31	736.60	29.07	918.61
Metronidazole	Oral	40.11	768.11	34.24	655.70
Ciprofloxacin	Intravenous	1.26	199.95	0.14	22.22
Ciprofloxacin	Oral	0.56	7.83	25.82	361.22
Amoxicillin/Clavulanic acid	Oral	34.90	244.30	126.38	884.66
Cefazolin	Intravenous	0	0	7.97	89.26
Doxycycline	Oral	0	0	22.83	531.94
Trimethoprim/Sulfamethoxazole	Oral	0	0	1.09	18.37
Cefprozil	Oral	11.24	724.98	0	0
Total		920.36	9513.92	788.56	7730.11

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4. Discussion

Implementation of the surgical antimicrobial prophylaxis programme in the present study resulted in increased compliance of prescribers with the guideline recommendations. It also led to improvements in the correct use of antibiotics, appropriate dose prescription, timing and duration of prophylaxis, and choice of route of administration. However, there was still a problem with the duration of prophylaxis. In a previous study by Segala et al. [28], it was found that after the implementation of an antimicrobial stewardship intervention, the appropriateness of prophylaxis duration was still not optimal, which was the most reported reason for non-compliant prescribing in the post-interventional survey of their study. Elyasi et al. [29] have also reported that there was a significant reduction in incorrect use of antibiotics after the implementation of an evidence-based guideline for gastrointestinal surgeries in a teaching hospital. Additionally, implementation of the guideline resulted in a reduction in the duration of antibiotic prophylaxis and a decrease in the prescription of inappropriate antibiotic doses, although this was not significant [29].

Implementation of the prophylaxis programme in the present study resulted in decreases in SSI rate, overall antibiotic consumption, and the cost of antibiotics. Sarang et al. [25] have reported that implementing SSI prevention guidelines, including proper antimicrobial prophylaxis, in two tertiary-care hospitals in Mumbai resulted in a significant decrease in prophylaxis costs; however, the SSI rates did not differ from those obtained after following the same international standards. A study conducted by van Kasteren et al. [30] in a multi-site, interventional study in Dutch hospitals revealed that intervention implementation led to improved quality of surgical antimicrobial prophylaxis as well as a reduction in antibiotic use and cost; however, there was an insignificant reduction in SSIs. Similarly, optimising antibiotic prophylaxis resulted in an insignificant reduction in the overall SSI rate from 5.4% to 4.5% in another study [31]. Furthermore, Fujibayashi et al. [32] have suggested that revising all relevant clinical pathways in invasive therapies may be highly effective in reducing antibiotic consumption and shortening the duration of antibiotic administration. It was found in the study conducted by Fujibayashi et al. [32] that the incidence of SSIs was not significantly different before and after the revisions made.

A study performed in a private hospital in Saudi Arabia by Kilan et al. [33] showed that implementation of interventions that could improve surgical antibiotic prophylaxis resulted in improved antibiotic selection, dosing, and timing of prophylaxis from 47.3% to 82.2% in patients undergoing gastrointestinal surgery (p < 0.001) [33]. Additionally, implementation of the interventions led to a reduction in SSI rate, although this change was not statistically significant.

Limitations

The main limitation of the present study was that the intervention was not implemented in a control group, as that was considered unethical. Second limitation was that some of the resulting changes were not statistically significant because there was a limited number of gastrointestinal surgeries that were performed in the hospital.

5. Conclusions

Implementation of the surgical antimicrobial prophylaxis programme included the establishment of a guideline, educational sessions, and a monthly revision of prescriptions. Our findings show that implementation of the programme resulted in decreases in antibiotic consumption, antibiotic prophylaxis cost, and the incidence of SSIs.

Author Contributions

Conceptualisation, N.J.A. and Z.S.A.; methodology, N.J.A.; software, A.M.A.; validation, A.K.A., E.E. and N.J.A.; formal analysis, A.A., N.J.A. and A.K.A.; investigation, N.J.A.; resources, A.M.A. and E.E.; data curation, A.A., Z.S.A. and A.A.A.; writing—original draft preparation, N.J.A.; writing—review and editing, A.H. and A.H.K.; visualisation, A.A.A. and M.F.B.; supervision, A.H.K. and A.H.; project administration, N.J.A. and Z.S.A.; funding acquisition, N.J.A. and M.F.B. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

The study was conducted in accordance with the Declaration of Helsinki, and approved by the Institutional Review Board of Al-Kharj Military Industries Corporation Hospital (protocol code 4101728 and date of approval).

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

Footnotes

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

Not applicable.

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PERMALINK

Implementing an Antimicrobial Stewardship Programme to Improve Adherence to a Perioperative Prophylaxis Guideline

Nehad J Ahmed

Ziyad S Almalki

Abdullah A Alfaifi

Ahmed M Alshehri

Abdullah K Alahmari

Emad Elazab

Alaa Almansour

Abdul Haseeb

Mohamed F Balaha

Amer H Khan

Roles

Abstract

1. Introduction

2. Materials and Methods

2.1. Setting

2.2. Data Collection

2.3. Inclusion and Exclusion Criteria

2.4. Interventions

2.5. Data Analysis

3. Results

3.1. Patients’ Characteristics

Table 1.

Table 2.

3.2. Appropriateness of Antimicrobials Used for Prophylaxis

Table 3.

Table 4.

3.3. Reduction in SSI Rate

Table 5.

3.4. Antimicrobial Use

Table 6.

Table 7.

4. Discussion

Limitations

5. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Conflicts of Interest

Footnotes

References

Associated Data

Data Availability Statement

ACTIONS

PERMALINK

RESOURCES

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