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Potential benefits of incentive spirometry following a rib fracture: a propensity score analysis

Published online by Cambridge University Press:  12 February 2019

Brice Lionel Batomen Kuimi ,
Antoine Lague ,
Valérie Boucher ,
Chantal Guimont ,
Jean-Marc Chauny ,
Jean-François Shields ,
Laurent Vanier ,
Miville Plourde  and
Marcel Émond Open the ORCID record for Marcel Émond [Opens in a new window]
Brice Lionel Batomen Kuimi
Affiliation:
Axe Santé des Populations et Pratiques optimales en santé, Centre de recherche du CHU de Québec – Université Laval, QC
Antoine Lague
Affiliation:
Axe Santé des Populations et Pratiques optimales en santé, Centre de recherche du CHU de Québec – Université Laval, QC Centre de Recherche sur les Soins et Services de Première Ligne de l'Université Laval, QB Faculté de médecine, Université Laval, QB
Valérie Boucher
Affiliation:
Axe Santé des Populations et Pratiques optimales en santé, Centre de recherche du CHU de Québec – Université Laval, QC Centre de Recherche sur les Soins et Services de Première Ligne de l'Université Laval, QB Faculté de médecine, Université Laval, QB Centre d'Excellence sur le Vieillissement de Québec, QB
Chantal Guimont
Affiliation:
Faculté de médecine, Université Laval, QB
Jean-Marc Chauny
Affiliation:
Hôpital du Sacré-Cœur de Montréal, QB Département de médecine familiale et médecine d'urgence, Université de Montréal, QB
Jean-François Shields
Affiliation:
Faculté de médecine, Université Laval, QB
Laurent Vanier
Affiliation:
Centre hospitalier de Charles-LeMoyne, Greenfield Park, QB
Miville Plourde
Affiliation:
Faculté de médecine, Université Laval, QB
Marcel Émond*
Affiliation:
Axe Santé des Populations et Pratiques optimales en santé, Centre de recherche du CHU de Québec – Université Laval, QC Centre de Recherche sur les Soins et Services de Première Ligne de l'Université Laval, QB Faculté de médecine, Université Laval, QB Centre d'Excellence sur le Vieillissement de Québec, QB Hôpital du Sacré-Cœur de Montréal, QB
*
Correspondence to: Dr. Marcel Émond, CHU de Québec – Université Laval, 1401, 18ième rue, Québec, QB G1J 1Z4; Email: marcelemond1@me.com

Abstract

Objectives

Incentive Spirometry is commonly used for respiratory recovery. The literature on incentive spirometry and its impact on patients with rib fracture is unclear and there are no recommendations regarding its use in the Emergency Department (ED), particularly in rib fracture patients, which are known for increasing the risk of pulmonary complication. Therefore, the objective of this study was to assess the use of incentive spirometry and to measure its impacts on delayed complications in patients discharged from the ED with confirmed rib fracture.

Methods

This is a planned sub-study of a prospective observational cohort recruited in 4 Canadians ED between November 2006 and May 2012. Non-admitted patients over 16 y.o. with at least one confirmed rib fracture on radiographs were included. Prescription of incentive spirometry was left to attending physician. Main outcomes were development of pneumonia, atelectasis, and hemothorax within 14 days. Propensity score matching analyses were performed.

Results

439 patients were included and 182 (41.5%) patients received incentive spirometry. There were 99 cases of hemothorax (22.6%), 103 cases of atelectasis (23.5%) and 4 cases of pneumonia (0.9%). The use of incentive spirometry was not protector for hemothorax [RR = 1.03 (0.66–1.64)] and atelectasis or pneumonia [RR = 1.07 (0.68–1.72)].

Conclusions

Our results suggest that unsupervised incentive spirometry use does not have a protective effect against delayed pulmonary complications after rib fracture. Further research should be conducted to assess the usefulness of incentive spirometry in specific injured population in the ED.

Résumé

Objectifs

La spirométrie incitative est parfois prescrite en vue d'encourager le rétablissement de la fonction respiratoire. Toutefois, peut de littérature est disponible sur la spirométrie incitative et ses effets chez les patients avec fracture de côtes, et il n'existe pas de recommandation sur son utilisation au département des urgences (DU), tout particulièrement pour les fractures de côtes, qui sont reconnues pour accroître le risque de complications pulmonaires. Cette étude visait donc à évaluer l'utilisation de la spirométrie incitative et à mesurer son impact sur l'incidence de complications tardives chez les patients ayant été libéré de l'urgence après une confirmation de fracture de côtes.

Méthode

Il s'agit d'une sous-étude planifiée d'une étude observationnelle de cohorte prospective, qui a eu lieu dans 4 DU au Canada, entre novembre 2006 et mai 2012. Des patients âgés de 16 ans et plus, non hospitalisés, avec au moins une fracture de côte confirmée par radiographie ont été sélectionnés. La décision de prescrire la spirométrie incitative était laissée à la discrétion du médecin traitant. Les principaux résultats consistaient en l'apparition d'une pneumonie, d'atélectasie ou d'un hémothorax dans les 14 jours suivant le traumatisme. Des analyses d'appariement des coefficients de propension ont été réalisées.

Résultats

Un total de 439 patients ont participé à l’étude, dont 182 (41,5%) ont été reçu la spirométrie incitative. 99 cas d'hémothorax (22,6%), 103 cas d'atélectasie (23,5%) et 4 cas de pneumonie (0,9%) ont été observés. Nos résultats indiquent que la spirométrie incitative ne semble pas un moyen de protection contre l'hémothorax (risque relatif [RR] = 1,03 [0,66–1,64]) ni contre l'atélectasie ou la pneumonie (RR = 1,07 [0,68–1,72]).

Conclusion

Nos résultats suggèrent que la spirométrie incitative non supervisée n'offrirait pas d'effet protecteur contre l'apparition tardive de complications pulmonaires à la suite d'une fracture de côtes. D'autres recherches sont nécessaires afin de valider la pertinence de prescrire la spirométrie incitative au DU, chez certains groupes de blessés plus spécifiques.

Keywords

Emergency departmentincentive spirometryrib fracture
Type
Original Research
Information
Canadian Journal of Emergency Medicine , Volume 21 , Issue 4 , July 2019 , pp. 464 - 467
Copyright
Copyright © Canadian Association of Emergency Physicians 2019 

CLINICIAN'S CAPSULE

What is known about the topic?

Literature regarding the impact of incentive spirometry on patients with rib fractures is unclear; there are no recommendations for its use in the emergency department (ED).

What did this study ask?

The objective of this study was to assess the impact of incentive spirometry on delayed complications in patients with rib fractures in the ED.

What did this study find?

Unsupervised incentive spirometry use does not have a protective effect against delayed pulmonary complications after a rib fracture.

Why does this study matter to clinicians?

Clear guidelines for incentive spirometry use for patients with rib fractures and further research to assess its usefulness in other ED populations are needed.

INTRODUCTION

Incentive spirometry is commonly used after surgery to maximize lung inflation.Reference Brunner, Smeltzer, Bare, Hinkle and Cheever1 Full lung expansion and decreased pleural pressure are known to prevent fluid build-up and complications such as atelectasis and pneumonia.Reference Brunner, Smeltzer, Bare, Hinkle and Cheever1, Reference Branson2

There are currently no recommendations regarding incentive spirometry use in patients with a rib fracture in the emergency department (ED). Chest injuries are a common complaint in the ED,Reference Rui and Kang3 and 75% of ED patients consulting for a minor thoracic injury (with or without a rib fracture) are not hospitalized. However, the risk of pulmonary complications increases with the number of rib fractures,Reference Chien, Chen and Han4 and patient management and admission/discharge follow-up plans are highly heterogeneous.Reference Shields, Emond, Guimont and Pigeon5 Clear recommendations should be made for incentive spirometry use in patients with a rib fracture consulting to the ED.

The objective of this study was, therefore, to evaluate the impact of incentive spirometry use in patients with a rib fracture discharged from the ED.

METHODS

Setting

This is a planned sub-analysis of a multicentre prospective cohort study.Reference Émond, Guimont and Chauny6 Patients were included if they 1) were ≥16 years old; 2) presented to a participating ED with at least one confirmed rib fracture on radiographs between 2006 and 2012; and 3) were discharged from the ED. An incentive spirometry prescription was left to the discretion of the attending physician. Participants received a five-minute teaching session by the ED nurse before discharge. Follow-up was conducted 7 and 14 days after the ED visit, with standard upright chest radiographs to ascertain potential delayed complications.

Outcomes

Three main delayed complications were assessed: hemothorax (any new pleural fluid collection), atelectasis (based on blinded radiologist reports), and pneumonia (according to the medical follow-up done by a physician) within 14 days of the ED visit. Because of the lower number of pneumonia cases, they were combined with atelectasis.

Statistical analysis

As the decision to prescribe incentive spirometry highly depends on a patient's clinical presentation, matching by propensity score was used to ensure a balance of covariates between the groups (incentive spirometry v. no incentive spirometry).Reference Williamson, Morley, Lucas and Carpenter7 Propensity scores were estimated using a logistic regression. We performed 1:1 matching based on logit of propensity scores.Reference Austin8 Matched analyses estimate the average treatment effect on the treated. The standardized difference (SD) was used to check the balance of covariates between matched and unmatched.Reference Austin8 Bootstrapping was used to estimate the confidence intervals (CI). All analyses were performed using SAS 9.4.Reference Coca-Perraillon9

Statistical Power

A propensity score match is a good alternative when adjusting for potential confounders is impossible with traditional conditional methods. Anticipating that about 30% of patients on IS would not be matched, we estimated a power of 80% (alpha of 0.05) to detect any relative risks outside the (0.6 and 1.67) interval.Reference Brookhart, Schneeweiss and Rothman10, Reference Stuart11

RESULTS

The initial cohort for the main study included a total of 1,474 patients.Reference Émond, Guimont and Chauny6 Of those, patients without a confirmed rib fracture (997), patients on warfarin (11), and patients lost to follow-up (27) were excluded, leaving a sample of 439 patients. Incentive spirometry was prescribed to 41.5% of these patients at ED discharge. Predictors of incentive spirometry administration include initial saturation, opiates, and number of rib fractures (Table 1 – Supplemental files). There were 99 (22.6%) cases of hemothorax (53 with incentive spirometry), 103 (23.5%) cases of atelectasis (49 with incentive spirometry), and 4 cases of pneumonia (0.9%) within the 14-day follow-up period.

Crude analyses reported a relative risk (RR) between incentive spirometry and hemothorax of 1.63 (95% CI 1.15–2.3) and 1.29 (95% CI 0.93–1.79) for atelectasis/pneumonia (Table 2).

Figures 1, 2, and 3 (Supplemental files) show the propensity score matching results. Balance of almost all covariates was achieved (SD < 0.1).

The RR of the matched sample was 1.03 (95% CI 0.66–1.61) for hemothorax and 1.07 (95% CI 0.68–1.72) for atelectasis or pneumonia (Table 2). Similar results were obtained, while adjusting for covariates with a standardized mean difference >0.1 (sex, trauma mechanism, and respiration rate); RR of 0.98 (95% CI 0.62–1.55) was determined for delayed hemothorax, and RR of 1.15 (95% CI 0.71–1.85) was demonstrated for delayed atelectasis or pneumonia.

DISCUSSION

Our results suggest that unsupervised incentive spirometry does not prevent delayed atelectasis, pneumonia, or delayed hemothorax within 14 days of an ED visit for a rib fracture. However, our 95% CIs were large and contained the null value, leading to similar results demonstrated by Tyson et al.,Reference Tyson, Kendig, Mabedi, Cairns and Charles12 who concluded that the use of unmonitored incentive spirometry after laparotomy did not demonstrate a significant improvement in pulmonary function.

Medical literature is not clear on the effect incentive spirometry on postoperative pulmonary complications (PPC). A 2001 systematic review showed no evidence supporting incentive spirometry use to decrease the incidence of PPC following cardiac or upper abdominal surgery.Reference Overend, Anderson and Lucy13 However, incentive spirometry was shown to reduce the incidence of PPC after coronary artery bypass grafts or major abdominal surgery.Reference Haeffener, Ferreira, Barreto, Arena and Dall'Ago14, Reference Westwood, Griffin and Roberts15 A more recent systematic review concluded that incentive spirometry has positive effects on preventing PPC.Reference Rupp, Miley and Russell-Babin16 Literature regarding incentive spirometry use in patients who sustained minor thoracic trauma is sparse, and current evidence concludes that the decision to use incentive spirometry following thoracic surgery should be made by physiotherapists.Reference Agostini and Singh17 To our knowledge, there is no specific study regarding incentive spirometry use in the ED, and, therefore, its use is based on surgical guidelines. Our findings suggest that unsupervised incentive spirometry does not impact the incidence of delayed complications in patients who are discharged with a rib fracture.

The absence of unmeasured confounders is one of the key assumptions while using propensity scores to estimate causal effects.Reference Stuart11 Therefore, if incentive spirometry assignment to patients is based on clinical judgment, controlling for prognostic factors alone in our propensity model leaves residual confounding by indication.Reference Bosco, Silliman and Thwin18 Age and a higher complication risk are confounding factors that could have influenced the medical decision to offer incentive spirometry. However, the majority of patients (75%) in the matched population were under the age of 65 years. Because of the limited number of seniors, further statistical analyses were not possible.

Patient adherence to the incentive spirometry treatment was not monitored that may have skewed results. Furthermore, chest X-rays were used to diagnose pulmonary complications. A new pleural effusion was considered a hemothorax, so the incidence of this complication may have been overestimated. Finally, 59 (32%) patients who used incentive spirometry were not matched, limiting the generalization of our findings.

CONCLUSION

To our knowledge, this study was the first to assess the use of unsupervised incentive spirometry for patients with a rib fracture in the ED. Our results were similar to those obtained in postoperative care studies. There was no decrease in post-discharge complications (pneumonia, atelectasis, and hemothorax) for rib fractures in patients who used incentive spirometry. A randomized control study should be done to assess the use of supervised incentive spirometry specifically in seniors or patients at high risk of delayed complications who are discharged from the ED.

Acknowledgements

We are grateful to all Emergency Physicians and research assistants at our participating centres who recruited and followed our study participants.

Competing interests

This work was supported by a grant from Fonds de la Recherche en Santé du Québec (FRSQ 14056).

SUPPLEMENTARY MATERIAL

The supplementary material for this article can be found at https://doi.org/10.1017/cem.2018.492.

References

REFERENCES

1.Brunner, LS, Smeltzer, SC, Bare, BG, Hinkle, JL, Cheever, KH. Brunner & Suddarth's textbook of medical-surgical nursing. Wolters Kluwer Health/Lippincott Williams & Wilkins; 2010.Google Scholar
2.Branson, RD. The scientific basis for postoperative respiratory care. Respir Care 2013;58(11):1974–84.Google Scholar
3.Rui, P, Kang, K. National Hospital Ambulatory Medical Care Survey: 2014 Emergency Department Summary Tables. Centers for Disease Control and Prevention, Statistics NCfH; 2014. Available at: https://www.cdc.gov/nchs/data/nhamcs/web_tables/2014_ed_web_tables.pdf (accessed January 1, 2019).Google Scholar
4.Chien, CY, Chen, YH, Han, ST, et al. The number of displaced rib fractures is more predictive for complications in chest trauma patients. Scand J Trauma Resusc Emerg Med 2017;25(1):19.Google Scholar
5.Shields, JF, Emond, M, Guimont, C, Pigeon, D. Acute minor thoracic injuries: evaluation of practice and follow-up in the emergency department. Can Fam Physician 2010;56(3):e11724.Google Scholar
6.Émond, M, Guimont, C, Chauny, JM, et al. Clinical prediction rule for delayed hemothorax after minor thoracic injury: a multicentre derivation and validation study. CMAJ Open 2017;5(2):E44453.Google Scholar
7.Williamson, E, Morley, R, Lucas, A, Carpenter, J. Propensity scores: from naive enthusiasm to intuitive understanding. Stat Methods Med Res 2012;21(3):273–93.Google Scholar
8.Austin, PC. An introduction to propensity score methods for reducing the effects of confounding in observational studies. Multivariate Behav Res 2011;46(3):399424.Google Scholar
9.Coca-Perraillon, M, ed. Local and global optimal propensity score matching. SAS Global Forum; 2007.Google Scholar
10.Brookhart, MA, Schneeweiss, S, Rothman, KJ, et al. Variable selection for propensity score models. Am J Epidemiol 2006;163(12):1149–56.Google Scholar
11.Stuart, EA. Matching methods for causal inference: a review and a look forward. Stat Sci 2010;25(1):121.Google Scholar
12.Tyson, AF, Kendig, CE, Mabedi, C, Cairns, BA, Charles, AG. The effect of incentive spirometry on postoperative pulmonary function following laparotomy: a randomized clinical trial. JAMA Surg 2015;150(3):229–36.Google Scholar
13.Overend, TJ, Anderson, CM, Lucy, SD, et al. The effect of incentive spirometry on postoperative pulmonary complications: a systematic review. Chest 2001;120(3):971–8.Google Scholar
14.Haeffener, MP, Ferreira, GM, Barreto, SSM, Arena, R, Dall'Ago, P. Incentive spirometry with expiratory positive airway pressure reduces pulmonary complications, improves pulmonary function and 6-minute walk distance in patients undergoing coronary artery bypass graft surgery. Am Heart J 2008;156(5):900.e1–.e8.Google Scholar
15.Westwood, K, Griffin, M, Roberts, K, et al. Incentive spirometry decreases respiratory complications following major abdominal surgery. Surgeon 2007;5(6):339–42.Google Scholar
16.Rupp, M, Miley, H, Russell-Babin, K. Incentive spirometry in postoperative abdominal/thoracic surgery patients. AACN Adv Crit Care 2013;24(3):255–63.Google Scholar
17.Agostini, P, Singh, S. Incentive spirometry following thoracic surgery: what should we be doing? Physiotherapy 2009;95(2):7682.Google Scholar
18.Bosco, JL, Silliman, RA, Thwin, SS, et al. A most stubborn bias: no adjustment method fully resolves confounding by indication in observational studies. J Clin Epidemiol 2010;63(1):6474.Google Scholar
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