Continuous and bimonthly publication
ISSN (on-line): 1806-3756

Licença Creative Commons
62508
Views
Back to summary
Open Access Peer-Reviewed
Artigo Original

Evaluation of the knowledge of health professionals at a pediatric hospital regarding the use of metered-dose inhalers

Avaliação do conhecimento sobre o uso de inaladores dosimetrados entre profissionais de saúde de um hospital pediátrico

Fábio Pereira Muchão, Sílvia La Regina Rodrigues Perín, Joaquim Carlos Rodrigues, Cláudio Leone, Luiz Vicente Ribeiro Ferreira Silva Filho

ABSTRACT

Objective: To evaluate health professionals working at a tertiary pediatric hospital in terms of their knowledge regarding the practical use of metered-dose inhalers. Methods: Practical and written tests on the use of metered-dose inhalers were applied to physicians, physical therapists, nurses and nursing assistants. A score from 0 to 10 was assigned to each evaluation, and median scores were calculated for each professional category. Questions with higher and lower correct values were identified, and a descriptive comparison was made regarding the performance of the various professional categories. Statistical analysis was performed using the Kruskal-Wallis method for comparison of medians. A sequential logistic multiple regression analysis was also performed. Results: A total of 30 resident physicians or interns in the pediatrics department, 23 attending physicians, 29 physical therapists, 33 nurses and 31 nursing assistants were evaluated. Resident physicians, physical therapists and attending physicians performed significantly better than did nurses and nursing assistants. Only resident physicians had a median score greater than 6. Conclusions: The health professionals evaluated, particularly the nurses and nursing assistants, who are directly involved in the practical use of metered-dose inhalers, possess insufficient knowledge regarding the use of such inhalers.

Keywords: Metered dose inhalers; Inhalation spacers; Asthma; Education, public health professional.

RESUMO

Objetivo: Avaliar os conhecimentos sobre o uso e manejo de inaladores pressurizados dosimetrados entre profissionais de um hospital pediátrico terciário. Métodos: Foram realizadas avaliações sobre o conhecimento do uso de inaladores pressurizados dosimetrados através de questionários teóricos e práticos, com médicos, fisioterapeutas, enfermeiras e auxiliares de enfermagem, atribuindo-se uma nota de 0 a 10 para cada avaliação. Calcularam-se as medianas das notas obtidas pelos profissionais de cada categoria, as questões com maiores e menores índices de erros, e foi feita a comparação descritiva do desempenho das diversas categorias profissionais. A análise estatística foi feita através do método de Kruskal-Wallis de comparação de medianas. Também foi realizada a análise através de regressão logística múltipla seqüencial. Resultados: Foram avaliados 30 médicos residentes ou estagiários de pediatria, 23 médicos assistentes, 29 fisioterapeutas, 33 enfermeiras e 31 auxiliares de enfermagem. Os médicos residentes, fisioterapeutas e médicos assistentes obtiveram desempenho significativamente superior aos dos enfermeiros e auxiliares de enfermagem. Apenas os médicos residentes obtiveram mediana superior a 6. Conclusões: O conhecimento a respeito do uso de inaladores dosimetrados entre os profissionais de saúde da instituição é insatisfatório, principalmente entre enfermeiros e auxiliares de enfermagem, diretamente envolvidos na aplicação prática dos inaladores dosimetrados.

Palavras-chave: Inaladores dosimetrados; Espaçadores de inalação; Asma; Educação profissional em saúde pública.

Introduction

Asthma is a significant public health problem worldwide, ranging in prevalence from 1 to 18%.(1) The ISAAC project showed that, in Brazil, the mean prevalence of active asthma (defined as episodes of wheezing within the last 12 months) was 24.3% and 19%, in first graders (aged 6-7 years) and adolescents (13 to 14 years), respectively, in the 2002-2003 period.(2) In Brazil, asthma is the third leading cause of hospitalization among children and young adults, greatly increases costs to the health care system, results in school absenteeism/inability to perform physical activities and can interfere with the psychosocial development of the child.(3)

Currently, there is a near-unanimous consensus that the use of anti-inflammatory drugs is indicated for the treatment of persistent asthma, since the role of inflammation in the pathophysiology of the disease is well recognized.(1,3,4)

The use of inhaled drugs is a basic aspect of the treatment of patients with asthma, in acute episodes as well as in maintenance therapy. For years, conventional nebulizers were the only inhalers available. With the advent of pressurized metered-dose inhalers, the delivery of drugs such as bronchodilators and corticosteroids into the respiratory tract was optimized, thereby decreasing local and systemic side effects.(5,6)

Various studies have demonstrated that the metered-dose inhaler is safe and efficacious, producing particles of 1 to 50 µm in diameter (1-to 5-µm diameter particles reach the distal portions of the tracheobronchial tree). In addition, it is portable, does not depend on an air compressor and uses a standardized dose.(7,8)

It is recommended that the inhaler be used together with a spacer, since that minimizes the difficulties in coordinating the triggering of the device simultaneously with the beginning of the inhalation. The spacer also provides less impact of particles on the oropharynx and upper airways, resulting in an up to two-fold increase in the pulmonary deposition of the drug. Some patients, however, do not care to use them due to their size, as well as to the need for cleaning and maintenance.(7-9)

Treatment failure in individuals with asthma frequently results from the incorrect use of metered-dose inhalers, which is typically a consequence of a lack of counseling by health professionals, many of whom are unfamiliar with the technique.(10) A multicenter study for the evaluation of inhalation technique among over 800 European health professionals and their patients, published in 1998, revealed that only 9% of patients, 15% of nurses and 28% of physicians used metered-dose inhalers correctly.(10) There have been no Brazilian or Latin-American studies regarding the skills of health professionals in the use of pressurized metered-dose inhalers.

The inhalation technique should be constantly re-evaluated, since there is evidence that it takes an average of ten visits for patients to learn it correctly, and this learning process depends on adequate technical knowledge on the part of the multiprofessional team.(11,12) The following are common errors: not exhaling before inhaling the drug; inhaling the medication either too rapidly or too slowly; and not holding the breath for 10 s after inhalation.

The correct technique for using metered-dose inhalers in school children, who should use the device standing or seated, with the thoracic and cervical spine held straight, consists of the following: shaking the inhaler; attaching it to the spacer with a mouthpiece, with the canister turned upward; exhaling calmly; placing the mouthpiece between the lips; pressing down on the inhaler and inhaling slowly and deeply; pausing, without exhaling, for 10 s; waiting (if two or more puffs are necessary) for 30 s to 1 min before repeating the process; and rinsing the mouth with running water. For suckling infants or newborn infants, who should use the device seated or standing, if possible, the procedure should be as follows: shake the inhaler; attach it to the spacer with mask, with the canister turned upward; place the mask on the face, covering nose and mouth to avoid air leaks; press down on the inhaler; count six to ten respirations, without interruption, in case the child cries, to avoid undesirable repetitions of the applied dose; if two or more puffs are necessary, repeat the process after 30 s to 1 min; and rinse the mouth with running water. As soon as children are old enough to place and keep their mouth on the mouthpiece during the procedure, the spacer with mouthpiece should be used instead of the spacer with mask.

The spacer should be cleaned once or twice a week with lukewarm running water and neutral detergent, without using brushes or towels, after which it should be allowed to air dry.

The University of São Paulo School of Medicine Hospital das Clínicas Institute for Children is a tertiary hospital where patients with chronic lung diseases are treated in the emergency room, intensive care unit, infirmary, outpatient clinic and nurseries. There have been no studies evaluating the knowledge regarding the use of pressurized metered-dose inhalers among the professionals working in the hospital.

Therefore, in order to determine the difficulties that might interfere with the appropriate counseling of the patients, we decided to determine the theoretical and practical knowledge of physicians, nurses and physical therapists in relation to the use of metered-dose inhalers.

Methods

This was an observational study involving a convenience sample of professionals working at the Institute for Children. We included a total of 146 professionals: 30 resident physicians or interns in pediatrics; 23 attending physicians; 29 physical therapists; 33 nurses; and 31 nursing assistants.

All participants were interviewed by one of the authors. In the first part of the interview, a professional registration form was filled out. The form includes information on length of service, area of service and current knowledge regarding inhalers (Annex 1).(13) Subsequently, a practical evaluation on the use of the metered-dose inhaler was conducted. The interviewees were given metered-dose inhalers containing placebo, plastic spacers of approximately 250 mL in volume (Luftchamber®; Luft, São Paulo, Brazil - and Aerochamber®; Trudell Medical, Ontario, Canada), with mask and mouthpiece, and were asked to demonstrate the use of these devices. Those who worked in areas such as the outpatient clinic, infirmary, ICU and emergency room demonstrated the use of inhalers in fictitious school-age patients (8 year olds) and suckling (11-month-old) infants, using the material provided. Professionals working in the nursery demonstrated the use of the device in school children and newborn infants.

The professional was observed during each step and was given a score of 0 when the step was omitted or demonstrated incorrectly, whereas a score of 1 was given when the step was demonstrated correctly. The ten items used in the evaluation are listed in Chart 1. The overall score ranged from 0 to 10.

The third part of the interview consisted of closed questions with direct responses regarding the following aspects: use of the spacer; type of spacer; waiting time between two consecutive puffs of the metered-dose inhaler; proper breathing technique prior to the inhalation; duration of the breath hold after inhalation; cleaning of the mouth after inhaler use (Annex 1). There were five questions, each worth 2 points, and the overall score obtained also ranged from 0 to 10.

After the evaluations, the professionals were given oral instruction on the correct use of the devices, after which printed materials, with illustrations, were provided.

Statistical analysis was performed using the Kruskal-Wallis method for comparison of medians, among the four groups of professionals and among the three intergroup tests performed. A sequential logistic multiple regression analysis included the following variables: professional category; more than five years or less than five years since graduation; having previously treated patients who used pressurized metered-dose inhalers; having asthma or having a relative who has asthma; having used pressurized metered-dose inhalers or having a relative who has. In the model, the dependent variable was the combined score on the tests, subdivided into two categories: < the median performance of the sample as a whole; and ≥the median performance of the sample as a whole. The choice of variables included in the multivariate model was based on their plausibility as possible determinants of the performance of the professional.

In all of the analyses, an αof 0.05 was adopted as the cut-off point to determine statistical significance. Only statistically significant results are shown in the corresponding tables.

The study design was approved by the Ethics in Research Committee of the Institution.

Results

The medians obtained in each type of test are presented in Table 1. The best medians, in absolute values, were obtained by resident physicians, followed by physical therapists, attending physicians, nurses and nursing assistants. Comparing the overall performance of the categories, the performance of resident physicians, physical therapists and adolescents and their performance on the practical attending physicians was significantly better than test for adolescents (p > 0.05 for both categories). that of nurses and nursing assistants (p < 0.001 Attending physicians, nurses and nursing assist-for all three categories). There were no significant ants performed significantly better on the practical differences in performance when we compared test for suckling infants than on the practical test attending physicians with residents (p > 0.05), resi-for adolescents (p < 0.001 for the three categodents with physical therapists (p > 0.05), physical ries), and their performance on the written test therapists with attending physicians (p > 0.05), and for adolescents was significantly better than their nurses with nursing assistants (p > 0.05). performance on the practical test for adolescents





Analyzing each category separately, we observed (p < 0.05 for attending physicians and p < 0.01 for that residents and physical therapists performed nurses/nursing assistants). There was no significant significantly better on the practical test for suck-difference between the practical test for suckling ling infants than on that for adolescents or on the infants and the written test for suckling infants in written test (p < 0.001 and p < 0.05, respectively, terms of the performance of the professionals in for both categories). For these same two profes-these three categories (p > 0.05 for all three). sional categories, there was no significant difference

In the sequential logistic multiple regression between their performance on the written test for model, the variables most strongly associated with better performance were, respectively, being a resident physician, being a physiotherapist, being an attending physician, and having previously treated patients who use metered-dose inhalers (Table 3). In all professional categories, the best medians were obtained on the practical test for suckling infants, and the worst were obtained on the practical tests for school children (Table 1).

On the practical tests for suckling infants and school children, the step most often performed incorrectly was step 10 (cleaning the spacer). On both practical tests, the steps related to shaking the inhaler and cleaning the mouth also presented high error indices. On the written tests, the question most often answered incorrectly was question 3 (regarding the waiting time between puffs).

On the practical tests for suckling infants and school children, respectively, the steps most often performed correctly were step 3 (using spacer) and step 1 (taking off the cap). On the written tests, the question most often answered correctly was question 1, which was related to the best technique for using metered-dose inhalers in suckling infants (Table 2).





Notably, the fact that the scores were higher on the practical test for suckling infants than on the practical test for school children can be, in great part, attributed to a common error made by health professionals, who do not use the spacer in school children, as was observed in 51.1% of the interviewees in the present study.

Discussion

In the overall evaluation conducted, we observed that resident physicians, physical therapists and attending physicians performed significantly better than did nurses and nursing assistants, who are directly involved in the practical application of medical prescriptions. It is noteworthy that only resident physicians obtained an overall median score >6.

Although we evaluated a convenience sample, the number of professionals interviewed constitutes a representative sampling of these categories of professionals working in the hospital in question.

Our results show that, principally because this is a referral center for pediatric health, the knowledge of these professionals regarding the use of metered-dose inhalers is considerably less than satisfactory, reinforcing a common finding in the medical literature: despite the greater efficiency of these devices over nebulizers for the delivery of inhaled medication (basically bronchodilators and corticosteroids), knowledge regarding their use has yet to be widely disseminated. These numbers confirm the findings of the previously mentioned multicenter study.(10) In that study, only 28% of the physicians, 15% of the nurses and 9% of the patients demonstrated the correct technique for using inhalers. The physicians performed significantly better than did the nurses and patients. Among the medical specialties studied, pediatricians performed significantly worse than did pulmonologists and allergists.(10) Other studies have obtained similar results.(14,15)

The lack of knowledge regarding this technique effectively limits the number of times that these devices are prescribed in comparison with conventional nebulizers, whether for the administration of maintenance medication, such as inhaled corticosteroids, or of bronchodilators for the treatment of exacerbations, at home or in the emergency room.

In reflection, we can analyze the advantages of pressurized metered-dose inhalers over conventional nebulization for use in emergency rooms. Respiratory diseases, including wheezing attacks (resulting from asthma or not), constitute the principal cause of childhood visits to hospitals. A patient with moderate or severe bronchospasm receives a minimum of three bronchodilator nebulizations in the emergency room. Since each nebulization is effective for 15 to 20 min, 45 min to 1 h will be spent on these procedures alone, and we cannot forget that conventional nebulizers are more costly, need periodic maintenance and need a feeding source in order to work.(16) In addition, nebulization demands up to 25 times greater doses of bronchodilators than do metered-dose inhalers.(17) If spacers and metered-dose inhalers are made available in emergency rooms, it will be possible to streamline the treatment of a great number of children, with clear benefit to clinical treatment, given the greater efficiency of these devices in delivering their medication to the respiratory tract. In addition, it is not possible to know how much drug provided by a nebulizer actually reaches the respiratory tract, since a large portion of the nebulized medication is dispersed into the air.(5,17,18) Some authors even prepared an extensive review of randomized studies, comparing the use of conventional nebulizers to that of metered-dose inhalers with spacers, in the delivery of bronchodilators for the management of acute asthma in adults and in children aged 2 or older. That review showed that children using metered-dose inhalers with spacers spent significantly less time in emergency rooms (mean, −0.47 h;95 CI:−0.58to−0.37),thandidchildrentreated with nebulization. In addition, the former group presented significantly lower heart rates.(16) The same authors, reviewing studies in which the use of conventional nebulizers was compared with that of metered-dose inhalers with spacers, in terms of the delivery of inhaled corticosteroids, found no quality publications on the issue regarding children.
A single, randomized controlled study, involving adults, showed that, for the delivery of budesonide, conventional nebulizers had advantages over metered-dose inhalers (higher peak expiratory flow values in the morning and afternoon, and lower rates in the use of relief bronchodilators). However, the doses of the drug delivered by the nebulizer (2000 to 8000 µg) were higher than those offered delivered by the metered-dose inhaler (1600 µg).(19)

An interesting finding is the high number of professionals (in all categories) who did not recommend the use of the spacer for school children. This results from a misconception that is widely disseminated among health professionals: that the function of the spacer is only to facilitate the use of inhaled medication by children who cannot coordinate respiratory movements during the use of the metered-dose inhaler. Although the spacer performs this function, its use also allows the larger particles (that do not reach the distal airways) to be retained in the device, whereas smaller particles are inhaled, reaching the distal airways with better treatment results.(5)Not using the spacer results in the retention of great part of the medication in the oropharynx, leading to higher risk of systemic absorption, with possible side effects, to the detriment of the desired pulmonary deposition of the medication.(5)

Oral hygiene after the use of inhaled corticosteroids is fundamental, principally in suckling infants and newborn infants. This decreases the possibility of the local side effect (oral candidiasis) and of long-term systemic side effects (retarded growth, decrease bone mineralization, etc.)(1,3) The high error index for the question regarding this issue among all professional categories indicates poor knowledge not only regarding the use of these inhalers but also regarding how to minimize the possible side effects of the inhaled corticosteroid therapy, which is generally a long-term treatment, but that, with correct professional guidance, is practically free of adverse events.(1,3)

In a randomized controlled study conducted in a hospital in Philadelphia, the skills of resident physicians in the use of pressurized metered-dose inhalers with spacers were evaluated before and after the implementation of a theoretical and practical educational program. The residents were divided into two groups, a study group and a control group, those in the latter being submitted only to the application of the written and practical questionnaire, at the beginning of the study and after 2 to 3 months, without the implementation of the educational program. The residents submitted to the theoretical and practical educational program performed significantly better, both in relation to their initial performance and in relation to the performance of the control group, at the end of the study.(13)

A similar intervention would be beneficial in order to improve the skills of professionals at the Institute for Children in the use of these inhalers. Short theoretical and practical classes given by pulmonologists could be provided, addressed to all professionals who work in the hospital. In conjunction with the dissemination of the written material provided to the participants in this study, which could be distributed to the entire hospital staff, these classes could adequately qualify these professionals in the practical application of the concepts regarding the use of pressurized metered-dose inhalers. Certainly, special attention would have to be given to the education of nurses and nursing assistants, since these professionals, who are responsible for the practical application of the inhalers, presented significantly worse performance than did the other professional categories. After this program of classes, a written and practical evaluation, similar to that shown in the present study, could be applied, with the objective of evaluating the true efficacy of this educational program.

A few limitations of the present study should be considered. Although the evaluations were not applied to professionals specializing in respiratory diseases, the fact that the population studied worked in a tertiary hospital might have affected the results. A similar study carried out in secondary hospitals or in basic health care clinics might obtain even worse results. Since Brazil is a country with a high prevalence of asthma, the knowledge of health professionals regarding techniques and inhalers should not be restricted to centers treating primarily cases of great complexity.

Future physicians, physical therapists and nurses should become familiar with these techniques as undergraduates so that, after graduation, they can not only apply their knowledge but also participate in the education of other health professionals.






References

1. Global Initiative for Asthma [homepage on the Internet]. Ontario: Global Initiative for Asthma [cited 2007 February12]. Global Initiative for Asthma -global strategy for asthma management and prevention. Available from: http://www. ginasthma.org/Guidelineitem.asp?l1=2&l2=1&intId=60

2. Solé D, , Wandalsen GF, Camelo-Nunes IC, Naspitz CK; ISAAC-Grupo Brasileiro. Prevalência de sintomas de asma, rinite e eczema atópico entre crianças e adolescentes brasileiros identificados pelo International Study of Asthma and Allergies (ISAAC) - Fase 3. J Pediatr. 2006;82(5):341-6.

3. Sociedade Brasileira de Pneumologia e Tisiologia. IV Diretrizes Brasileiras para o Manejo da Asma. J Bras Pneumol. 2006; 32 Supl 7: S447-S74.

4. O'Byrne PM, Pedersen S. Measuring efficacy and safety of different inhaled corticosteroid preparations. J Allergy Clin Immunol. 1998;102(6 Pt 1):879-86.

5. Duerden M, Price D. Training Issues in the Use of Inhalers. Dis Manage Health Outcomes. 2001;9(2):75-87.
6. Laube e BL. In vivo measurements of aerosol dose and distribution: clinical relevance. J Aerosol Med. 1996;9(Suppl 1):S77-S91.

7. Brand PL, Roorda RJ. Drug Delivery in Pediatric Patients with Asthma: Spacer Devices vs Nebulizers for [beta]2 Agonists. Am J Drug Delivery. 2003;1(1):61-70.

8. Biggart E, Bush A. Antiasthmatic drug delivery in children. Paediatr Drugs. 2002;4(2):85-93.

9. Demirkan K, Tolley E, Mastin T, Soberman J, Burbeck J, Self
T. Salmeterol administration by metered-dose inhaler alone vs metered-dose inhaler plus valved holding chamber. Chest. 2000;117(5):1314-8.10.
Plaza V, Sanchis J. Medical personnel and patient skill in the use of metered dose inhalers: a multicentric study. CESEA Group. Respiration. 1998;65(3):195-8.

11. Leal O. Análise de fatores potencialmente agravantes da asma brônquica em pacientes tratados com corticosteróides sistêmicos [thesis]. São Paulo: Universidade de São Paulo; 1998.

12. Chopra N, Oprescu N, , Fask A, Oppenheimer J. Does introduction of new "easy to use" inhalational devices improve medical personnel's knowledge of their proper use? Ann Allergy Asthma Immunol. 2002;88(4):395-400.

13. Amirav I, Goren A, Kravitz RM, Pawlowski NA. Physician-targeted program on inhaled therapy for childhood asthma. J Allergy Clin Immunol. 1995;95(4):818-23.

14. Grydeland TB, Methlie P, Bakke PS. [Instructing patients in the correct use of inhalation devices] [Article in Norwegian]. Tidsskr Nor Laegeforen. 2006;126(3):312-4.

15. Owayed d A, Al-Ateeqi W, Behbehani N. Proficiency of pediatricians in the use of inhaled medication delivery systems for the management of asthma. J Asthma. 2006;43(6):459-62.

16. Cates CJ, Crilly JA, Rowe BH. Holding chambers (spacers) versus nebulisers for beta-agonist treatment of acute asthma. Cochrane Database Syst Rev. 2006;(2):CD000052.

17. Cates C. Spacers and nebulisers for the delivery of beta-agonists in non-life-threatening acute asthma. Respir Med. 2003;97(7):762-9.

18. Ribeiro JD. Aerossóis s e espaçadores na crise aguda de asma. Evolução e hora de mudar a rotina. J Pediatr. 2005;81(4):274-6.

19. Cates CJ, Bestall J, Adams s N. Holding chambers versus nebulisers for inhaled steroids in chronic asthma. Cochrane Database Syst Rev. 2006;(1): CD001491.

__________________________________________________________________________________________________________________
Study carried out at in the Pediatric Pulmonology Department of the University of São Paulo School of Medicine Hospital das Clínicas Institute for Children, São Paulo (SP) Brazil.
1. Pediatric Pulmonologist. Pediatric Pulmonology Department of the University of São Paulo School of Medicine Hospital das Clínicas Institute for Children, São Paulo (SP) Brazil.
2. Collaborating Physician. Pediatric Pulmonology Department of the University of São Paulo School of Medicine Hospital das Clínicas Institute for Children, São Paulo (SP) Brazil.
3. Head of the Pediatric Pulmonology Department of the University of São Paulo School of Medicine Hospital das Clínicas Institute for Children, São Paulo (SP) Brazil.
4. Associate Professor. Maternal and Infant Health Department of the University of São Paulo School of Public Health, São Paulo (SP) Brazil.
5. Attending Physician. Pediatric Pulmonology Department of the University of São Paulo School of Medicine Hospital das Clínicas Institute for Children, São Paulo (SP) Brazil.
Correspondence to: Fábio Pereira Muchão. Rua Vergueiro, 8424, bloco 05, apto 104, CEP 04272-300, Ipiranga, São Paulo, SP, Brasil.
Tel/Fax 6162-6724. E-mail: fabiomuchao@gmail.com
Submitted: 12 February 2007. Accepted, after review: 7 May 2007.

Indexes

Development by:

© All rights reserved 2024 - Jornal Brasileiro de Pneumologia