Effect of Total Compression Time and Rate (Slope) on Incidence of Symptomatic ETD and MEB: A Phase II Prospective Study.

NCT ID: NCT04776967

Last Updated: 2021-08-19

Basic Information

• Recruitment Status: COMPLETED
• Clinical Phase: NA
• Total Enrollment: 300 participants
• Study Classification: INTERVENTIONAL
• Study Start Date: 2014-09-08
• Study Completion Date: 2021-02-28

Brief Summary

Eustachian tube dysfunction (ETD) and middle ear barotrauma (MEB) are common reported complications during hyperbaric oxygen treatment. The Phase I study data was the first to demonstrate a statistically significant decrease in the occurrence of symptomatic ETD and middle ear barotrauma (MEB). The Phase I Trial suggested the total time interval and rate (slope) of compression (ROC) may be a determining factor in ETD and MEB. This Phase II study investigates an optimal total time interval and rate of compression to reduce ETD and MEB when considering each multiplace treatment (with multiple patients) as the unit of observation collectively as a group, rather than for each individual patient.

Data will be collected prospectively on group patient-treatment exposures. The investigators randomly assigned patient-treatment group exposures to four different time interval and rate (slope) of compression. These total time intervals of compression and rates (slopes) of compression are identical to those used in the Phase I trial. All patients experiencing symptoms of ETD and MEB requiring compression stops will be evaluated post treatment to confirm the presence of ETD and MEB using the O'Neill Grading System (OGS). Data will be analyzed using the IBM-SPSS statistical software program.

The number of compression holds observed in each of the 4 compression schedules, similar to ther Phase I trial will be recorded. Patients who are symptomatic and require compression stops (as in the Phase I trial) using a United States Navy Treatment Table 9 (USN-TTN9) during elective hyperbaric oxygen treatments in a Class A multiplace hyperbaric chamber will be analyzed. Analysis using descriptive and inferential statistics will be applied to the patients requiring first stops in the 4 compression profiles. This Phase II study increases the sample size of treatments and they will be combined with the total number of treatments used in the original phase I study. This will increase power to facilitate detailed descriptive analysis and to determine if the findings are robust in the phase I study.

Detailed Description

Eustachian tube dysfunction (ETD) and middle ear barotrauma (MEB) are common reported complications during hyperbaric oxygen treatment. The investigators Phase I study data was the first to demonstrate a statistically significant decrease in the occurrence of symptomatic ETD and middle ear barotrauma (MEB). The Phase I Trial suggested the total time interval and rate (slope) of compression (ROC) may be a determining factor in ETD and MEB. This Phase II study investigates an optimal rate of compression to reduce ETD and MEB when considering each multiplace treatment (with multiple patients) as the unit of observation as a group, rather than for each individual patient.

Data will be collected prospectively on group patient-treatment exposures. The investigators will randomly assign patient-treatment group exposures to four different time interval and rate (slope) of compression. All patients, within every patient-treatment group exposure, received all 4 compression profiles (CP) on a rotating basis, in effect having patients serve as their own controls in a crossover design and to reduce the risk of treatment order on the effects observed. These compression rates and slopes were identical to those used in the Phase I trial. All patients experiencing symptoms of MEB requiring compression stops will be evaluated post-treatment for the presence of ETD and MEB using the O'Neill Grading System (OGS) for ETD/MEB.

For approximately 10 years, the investigators hyperbaric center used a routine daily multiplace chamber treatment protocol to a depth of 45 feet of seawater (fsw) (modified U.S. Navy Treatment Table 9). The chamber was compressed over a 10-minute time interval representing a 4.5 fsw/minute uniform rate of compression. This 4.5-fsw/minute linear rate (slope) of compression rate was maintained throughout the total 10-minute time interval of treatment and will be used as a baseline compression rate to compare all other compression schedules [total compression time interval/compression rates (slopes)]. The investigators will prospectively collect data on patient-treatment group exposures after formalizing four different compression schedules each including a unique combination of compression rate (slope) and time intervals of compression. This was similar to the Phase I study.

Data will be collected prospectively on all patients recruited and receiving treatment from February 11, 2019, and February 10, 2020, and combined with the data obtained in our Phase I trial collected from September 8, 2014 to September 8, 2016. This Phase II study defines the unit of observations as a multiplace patient-treatment group exposure rather than individual patient treatment exposures. This approach was considered appropriate as a treatment stop or hold in a multiplace chamber affects all other patient occupants in the same treatment group exposure.

To mitigate the risk of confounding, only the first stop will be used as the stop or hold indicator for that particular patient-treatment group exposure. Data will be collected on the patient(s) experiencing the stop or hold. All patients will undergo pre-treatment video otoscopy with baseline tympanic membrane (TM) photos and video of TM motion documenting the patients ability to equalize. This is used to assess potential Eustachian tube patency and proper equalization performance to help exclude individual patient technique as a confounding variable. Photos will be repeated at the end of treatment on any patient(s) complaining of symptoms referable to ETD/MEB that require a stop during compression.

Multiple stops for the same patient on the same treatment will not be considered. Only the first compression stop or hold during each treatment exposure will be recorded or assigned as a patient-treatment stop representing that particular patient-treatment group exposure. Compression stops will be made when any patient experiences difficulty equalizing (requests a stop or complains of ear discomfort of any type).

Repeat video otoscopy will be conducted on all patients complaining of symptoms referable to ETD or MEB to objectively document the grade of barotrauma at the end of the treatment. The OGS system will be used to record the severity of the ETD or MEB. The depth of the stop, the treatment number for that particular patient, and the actions taken to alleviate the symptoms during equalization will be recorded.

The depth of the compression stop will be recorded in feet of seawater (fsw) as will be the ascent (fsw) required for the patient to clear the middle ear pressure and relieve the symptoms. The patients symptoms must be resolved, rendering the patient asymptomatic and able to continue the treatment compression profile. All team members (physicians, nurses, and technicians) present and working on the day of the exposure, are responsible for viewing the patients pre and post tympanic membrane photos and determining the grade of barotrauma using the OGS criteria.

All stops were categorized under the respective compression protocol used for that particular patient-treatment group exposure. Data will then compared using both descriptive and inferential statistical analysis including the risk difference, odds ratio (OR), two-tailed Chi Square analysis using α=0.05, and outcomes will be studied separately in a logistic regression analysis.

Conditions

Eustachian Tube Dysfunction; Middle Ear Barotrauma; Middle Ear Disease; Middle Ear; Injury; Pressure Injury; Ear Barotrauma

Study Design

• Allocation Method: RANDOMIZED
• Intervention Model: CROSSOVER
• Primary Study Purpose: PREVENTION
• Blinding Strategy: SINGLE

Study Groups

Compression Profile 4

Compression Profile/Schedule 4 = 10 minute linear, Total Time Interval of Compression to treatment depth = 10 minutes, Rate (slope) of compression = Linear rate of compression = 4.5 fsw/min to arrival at treatment depth 45 fsw

Group Type: ACTIVE_COMPARATOR

Hyperbaric Compression Profile

Intervention Type: PROCEDURE

A total of 4 randomized hyperbaric treatment compression profiles (accepted standards of care) will be alternated over the patients course of treatment on a daily basis daily to the prescribed treatment depth.

Compression Profile 3

Compression Profile/Schedule 3 = 10 minute non-linear, Total Time Interval of Compression to treatment depth = 10 minutes Rate (slope) of compression = Non-Linear rate of compression = 3 fsw/min to a depth of 17 fsw, then 5 fsw/min up to a depth of 38.5 fsw, then 6.5 fsw/min to arrival at the treatment depth of 45 fsw

Group Type: ACTIVE_COMPARATOR

Hyperbaric Compression Profile

Intervention Type: PROCEDURE

A total of 4 randomized hyperbaric treatment compression profiles (accepted standards of care) will be alternated over the patients course of treatment on a daily basis daily to the prescribed treatment depth.

Compression Profile 2

Compression Profile/Schedule 2 = 15 minute linear, Total Time Interval of Compression to treatment depth = 15 minutes Rate (slope) of compression = Linear rate of compression = 4.5 fsw/min to arrival at the treatment depth 45 fsw

Group Type: ACTIVE_COMPARATOR

Hyperbaric Compression Profile

Intervention Type: PROCEDURE

A total of 4 randomized hyperbaric treatment compression profiles (accepted standards of care) will be alternated over the patients course of treatment on a daily basis daily to the prescribed treatment depth.

Compression Profile 1

Compression Profile/Schedule 1 = 15 minute non-linear, Total Time Interval of Compression to treatment depth = 15 minutes Rate (slope) of compression = Non-Linear rate of compression = 2 fsw/min to a depth of 13 fsw, then 3 fsw/min up to a depth of 35 fsw, then 5 fsw/min to arrival at the treatment depth of 45 fsw

Group Type: ACTIVE_COMPARATOR

Hyperbaric Compression Profile

Intervention Type: PROCEDURE

A total of 4 randomized hyperbaric treatment compression profiles (accepted standards of care) will be alternated over the patients course of treatment on a daily basis daily to the prescribed treatment depth.

Interventions

Hyperbaric Compression Profile

A total of 4 randomized hyperbaric treatment compression profiles (accepted standards of care) will be alternated over the patients course of treatment on a daily basis daily to the prescribed treatment depth.

Intervention Type: PROCEDURE

Other Intervention Names

Hyperbaric Compression Schedule

Eligibility Criteria

Inclusion Criteria

-

Exclusion Criteria

-

• Eligible Sex: ALL
• Accepts Healthy Volunteers: No

Sponsors

Northwell Health

OTHER

Sponsor Role: lead

Responsible Party

Owen J O'Neill, MD, MPH

Medical Director Division of Undersea & Hyperbaric Medicine

Responsibility Role: PRINCIPAL_INVESTIGATOR

Principal Investigators

Owen J O'Neill, MD, MPH

Role: PRINCIPAL_INVESTIGATOR

Phelps Hospital Northwell Health

Locations

Phelps Hospital Northwell Health

Sleepy Hollow, New York, United States

Countries

United States

References

1. Beuerlein M, Nelson RN, DB W. Inner and middle ear hyperbaric oxygen induced barotrauma. The Laryngoscope. 1997;107(10):1350-6. 2. EM C. Side effects of hyperbaric oxygen therapy. Undersea & Hyperbaric Medicine : Journal of the Undersea and Hyperbaric Medical Society, Inc. 2014;41(3):253-7. 3. Heyboer M, Wojcik SM, Grant WD, Chambers P, Jennings S, P A. Middle ear barotrauma in hyperbaric oxygen therapy. Undersea & Hyperbaric Medicine Journal of the Undersea and Hyperbaric Medical Society, Inc, . 2014;41(5):393-7. 4. Lima MA, Farage L, Cury MC, FJ B. Update on middle ear barotrauma after hyperbaric oxygen therapy-insights on pathophysiology. International Archives of Otorhinolaryngology. 2014;18(2):204-9. 5. Ng AWA, Muller R, J O. Incidence of middle ear barotrauma in staged versus linear chamber compression during hyperbaric oxygen therapy: a double blinded, randomized controlled trial. Undersea Hyperb Med: Journal of the Undersea and Hyperbaric Medical Society, Inc. 2017;44(2):101-7. 6. Plafki C, Peters P, Almeling M, Welslau W, R B. Complications and side effects of hyperbaric oxygen therapy. Aviation, Space, and Environmental Medicine. 2000;71(2):119-24. 7. Toklu AS, Shupak A, Yildiz S, Aktas S, Ertracht O, Ay H, et al. Aural barotrauma in submarine escape: is mastoid pneumatization of significance? The Laryngoscope. 2005; 115(7):1305-9. 8. Vahidova D, Sen P, Papesch M, Zein-Sanchez MP, PH M. Does the slow compression technique of hyperbaric oxygen therapy decrease the incidence of middle ear barotrauma? J Laryngol Otol. 2006;120(6):446-9. 9. Varughese L, O'Neill OJ, Marker J, Smykowski E, Dayya D. The Effect of Compression Rate and Slope on the Incidence of Symptomatic Eustachian Tube Dysfunction Leading to Middle Ear Barotrauma: A Phase 1 Prospective Study. Undersea & Hyperbaric Med: Journal of the Undersea and Hyperbaric Medical Society, Inc. 2019;46(2):95-100. 10. AA B. Diving medicine. American Journal of Respiratory and Critical Care Medicine. 2014;189(12):1479-86. 11. Fitzpatrick DT, Franck BA, Mason KT, SG S. Risk factors for symptomatic otic and sinus barotrauma in a multiplace hyperbaric chamber. Undersea & Hyperbaric Medicine : Journal of the Undersea and Hyperbaric Medical Society, Inc. 1999;26(4):243-7. 12. Goplen FK, Gronning M, Aasen T, SHG N. Vestibular effects of diving -- a 6-year prospective study. . Occup Med 2010;60(1):43-8. 13. Hadanny A., Meir O, Bechor Y., Fishlev G, Bergan J, S E. The safety of hyperbaric oxygen treatment--retrospective analysis in 2,334 patients. Undersea & Hyperbaric Medicine: Journal of the Undersea and Hyperbaric Medical Society, Inc. 2016;43(2):113-22. 14. Mozdzanowski C, GA P. Peripheral neuropathy may increase the risk for asymptomatic otic barotrauma during hyperbaric oxygen therapy: Research report. Undersea & Hyperbaric Medicine: Journal of the Undersea and Hyperbaric Medical Society, Inc. 2014;41(4):267-72. 15. RW S. Controlling the rate of middle ear barotrauma: An editorial perspective. Undersea & Hyperbaric Medicine : Journal of the Undersea and Hyperbaric Medical Society, Inc. 2014;41(5):355-6. 16. O'Neill OJ, ED W. The O'Neill grading system for evaluation of the tympanic membrane: A practical approach for clinical hyperbaric patients. Undersea & Hyperbaric Medicine : Journal of the Undersea and Hyperbaric Medical Society, Inc. 2015;42(3):265-71. 17. Mozdzanowski C, GA P. Peripheral Neuropathy May Increase the Risk for Asymptomatic Otic Barotrauma During Hyperbaric Oxygen Therapy: Research Report. Undersea and Hyperbaric Medicine Journal of Undersea and Hyperbaric Medical Society. 2014;41(4):267-72. 18. Nasole E, Zanon V, Marcolin P, G B. Middle Ear Barotrauma During Hyperbaric Oxyeg Therapy; A Review of Occurrences in 5962 Patients. Undersea & Hyperbaric Med: Journal of the Undersea and Hyperbaric Medical Society. 2019;46(2):101-6.

Reference Type: BACKGROUND

O'Neill OJ, Dayya D, Varughese L, Marker JA, Perez L, Dayya M. The effect of total compression time and rate (slope) of compression on the incidence of symptomatic Eustachian tube dysfunction and middle ear barotrauma: a Phase II prospective study. Undersea Hyperb Med. 2021 Third Quarter;48(3):209-219.

Reference Type: DERIVED

PMID: 34390625 (View on PubMed)

Other Identifiers

Compression Hyperbaric II

Identifier Type: -

Identifier Source: org_study_id