Deep venous thrombosis prophylaxis in trauma: improved compliance with a novel miniaturized pneumatic compression device☆
Article Outline
Abstract
Objective
Intermittent pneumatic compression (IPC) devices prevent lower-extremity deep venous thrombosis (LEDVT) when used properly, but compliance remains an issue. Devices are frequently discontinued when patients are out of bed, and they are rarely used in emergency departments. Trauma patients are at high risk for LEDVT; however, IPCs are underused in this population because of compliance limitations. The hypothesis of this study was that a new miniaturized, portable, battery-powered pneumatic compression device improves compliance in trauma patients over that provided by a standard device.
Methods
This was a prospective trial in which trauma patients (mean age, 46 years; revised trauma score, 11.7) were randomized to DVT prophylaxis with a standard calf-length sequential IPC device (SCD group) or a miniaturized sequential device (continuous enhanced-circulation therapy [CECT] group). The CECT device can be battery-operated for up to 6 hours and worn during ambulation. Timers attached to the devices, which recorded the time each device was applied to the legs and functioning, were used to quantify compliance. For each subject in each location during hospitalization, compliance rates were determined by dividing the number of minutes the device was functioning by the total minutes in that location. Compliance rates for all subjects were averaged in each location: emergency department, operating room, intensive care unit, and nursing ward.
Results
Total compliance rate in the CECT group was significantly higher than in the SCD group (77.7% vs. 58.9%, P = .004). Compliance in the emergency department and nursing ward were also significantly greater with the CECT device (P = .002 and P = .008 respectively).
Conclusions
Previous studies have demonstrated that reduced compliance with IPC devices results in a higher incidence of LEDVT. Given its ability to improve compliance, the CECT may provide superior DVT prevention compared with that provided by standard devices.
Intermittent pneumatic compression (IPC) devices prevent lower-extremity deep venous thrombosis (LEDVT) in most patient populations.1, 2, 3 Their primary mechanism of action is an increase in venous flow velocities in the lower extremities, which reduces the stasis component of Virchow's triad.4 Some evidence exists that the devices also reduce thrombosis by increasing endogenous fibrinolysis or by affecting other hemostatic factors.5, 6 The devices consist of sleeves that wrap around the legs or feet and are attached to a pump. The pump causes the sleeves to inflate, which compresses veins and ejects blood from the legs. However, to be effective, they must be in use continuously; there is no effect that lasts beyond the time they are applied and functioning on the legs.
Compliance remains a major problem with standard devices; the pumps require connection to an external power source and are often discontinued when patients are out of bed. Nursing staff may not be vigilant in ensuring that the devices are functioning, and patients may remove the sleeves or disconnect the devices if they find them uncomfortable. Additionally, IPC devices are rarely used in the emergency department (ED) because patients travel frequently for radiographic studies and other procedures. The traditional view is that patients do not remain in the ED long enough for development of LEDVT; however, in the current climate of medical care, shortages of hospital beds mean that patients often spend up to 12 hours in the ED.
DVT prophylaxis in trauma patients is a particularly difficult problem. The risk of venous thromboembolism (VTE) is high,7, 8, 9 and evidence suggests that a significant number of LEDVTs and pulmonary embolisms occur very early after injury.10 Some clinicians are uncomfortable with the use of anticoagulants in the early period after injury because of the risk of bleeding.11, 12 The use of pneumatic compression devices for LEDVT prophylaxis in this population eliminates this risk.
Recently, a new miniaturized, portable, battery-powered pneumatic compression device has been developed (WizAir DVT Continuous Enhanced Circulation Therapy [CECT]; Medical Compression Systems, Ltd, Or-Akiva, Israel), which reduces the compliance problems associated with standard devices. Inclusion of a battery allows the CECT device to function for 5 to 7 hours without attachment to an external power source. The small size and weight (690 g) of the device allow it to be worn while ambulating.
The hypothesis of this study was that the CECT device would improve compliance in trauma patients over that provided by a standard device. Improved compliance should reduce the risk of LEDVT.
Methods
Devices
Two pneumatic compression devices were used in this study. One was a traditional calf-length sequential IPC device (SCD Sequential Compression Device Model 7325 and Knee Length sleeve Model 5329; Tyco- Kendall Manchester, Mass; SCD group), which requires attachment to an external power source to function. The second was a miniaturized, battery-powered sequential device (WizAir DVT Continuous Enhanced Circulation Therapy, Calf sleeve Model 201-C-1; Medical Compression Systems Inc;. CECT group) weighing 690 g, which can function from an internal battery for up to 6 hours. The device recharges when attached to an external power source with an AC adapter; throughout the study, the device was recharged in this fashion. The internal batteries were not changed during the study.
The compression profiles for the two devices are similar: the SCD system uses 11 seconds of compression followed by 60 seconds of decompression, and a maximum pressure during inflation of 50 mm Hg. The CECT device uses 8 seconds of compression followed by 52 seconds of decompression, and an average maximum sleeve pressure during inflation of 50 mm Hg. The pumping characteristics of the two devices, measured as increases in popliteal and femoral peak systolic venous flow velocities, are similar (Table I).
Table I. Venous flow velocities∗ generated by study devices
| SCD† | CECT† | P‡ | |||
|---|---|---|---|---|---|
| Maximal vs baseline | SCD vs CECT | ||||
| Common femoral venous velocity, cm/sec | Baseline | 13.07 ± 3.79 | 13.63 ± 5.36 | <.001 | .006§ |
| Maximal | 16.38 ± 3.41 | 19.34 ± 6.78 | |||
| Popliteal venous velocity, cm/sec | BaselineMaximal | 8.05 ± 2.0119.97 ± 4.66 | 8.67 ± 3.1322.40 ± 11.37 | <.001 | .54 |
∗ Measured with duplex ultrasound scanner by using a linear 7.5-MHz transducer. |
† Data expressed as mean ± SEM. |
‡ ANOVA with repeated measures. |
§ CECT achieved significantly higher femoral venous velocity than SCD. |
Protocol
This protocol was approved by the Institutional Review Board at The University of Texas Medical Branch (UTMB), and informed consent was obtained from all study participants before enrollment. Trauma patients were enrolled upon arrival to the ED. Eligible subjects included those who experienced motor vehicle accidents, penetrating trauma, hip fractures, spinal cord injuries, and head injuries. All participants were projected to remain hospitalized for ≥12 hours and to be able to have IPC devices applied to both legs, and had no history of venous thromboembolism or requirement for systemic anticoagulation. Only adult subjects (≥18 years) were eligible. Subjects were randomized to treatment with the SCD or the CECT device, and compression was begun immediately after randomization. Counters were affixed to the devices to monitor the amount of time the device was applied and pumping. Nursing staff and physicians were educated regarding the use of the two devices before initiation of the study. They were instructed to use the devices whenever possible according to protocols already in place at UTMB, which include attaching the SCD device to a power source when possible and using the battery function of the CECT device at all times when necessary. Devices were monitored at least two times daily to ensure the timers were functioning, but no attempts by the study investigators were made to influence the use of the devices once the patient was enrolled in the study. All other aspects of patient care, including the decision to use low-dose unfractionated or low–molecular weight heparin for additional LEDVT prophylaxis, were at the discretion of the treating physician. Enrollment in the study ended at the time of hospital discharge or diagnosis of VTE.
Total compliance was quantified as the ratio of the total number of minutes each device was pumping on a subject divided by the total number of minutes the subject was enrolled. For each subject, a percentage was calculated by multiplying the ratio by 100; data for all subjects in each group were pooled. Compliance rates for each device in each site (ED, operating room [OR], intensive care unit [ICU], nursing ward [WARD]) were also calculated. Transportation minutes were added to the site to which the patient was moving.
Statistical analysis
All data were expressed as mean ± SEM. The proportional characteristics of the two groups were compared with the Fisher exact test for frequencies and the independent Student t test for continuous data. The compliance rates were analyzed with the independent Student t test or a-parametric test (Mann-Whitney U test) when the values were not characterized by normal distribution. P values were assessed at the .05 level of significance.
Results
Subjects
Thirty three subjects completed the study. The mean age, sex, time until enrollment, total enrollment, revised trauma score, the use of pharmacologic prophylaxis, and frequencies of patient locations for each group are summarized in Table II. Types of traumatic injuries are summarized in Table III. There were no significant differences in age or sex between the two groups (P = .40 and P = .73, respectively). The time from arrival in the ED to enrollment was slightly longer in the CECT group, but the difference between the two groups was not statistically significant (P = .06). The total enrollment time was similar between the two groups (P = 1.00). The revised trauma score was not statistically different between the two groups (P = .94), nor were the types of traumatic injuries experienced by the patients (P = .398). Additional pharmacologic prophylaxis (low-dose unfractionated or low–molecular weight heparin) was not statistically different between the two groups (P = 1.00), nor were frequencies of patient locations (P = .77). There were no significant differences in the mechanisms of injury (Table III, P = .54). No subject developed signs or symptoms of venous thromboembolism during the study.
Table II. Patient characteristics
| SCD | CECT | P | |
|---|---|---|---|
| Number of subjects | 16 | 17 | |
| Age (mean ± SEM, years) | 51.4 ± 5.3 | 45.4 ± 4.7 | 0.404∗ |
| Sex (M:F) | 9:7 | 11:6 | 0.728† |
| Time until enrollment (mean ± SEM, minutes) | 126 ± 19 | 186 ± 24 | 0.058∗ |
| Total enrollment (mean ± SEM, minutes) | 7090 ± 2008 | 7089 ± 1563 | 1.000∗ |
| Revised trauma score | 11.75 ± 0.11 | 11.76 ± 0.16 | 0.941∗ |
| Use of additional pharmacologic prophylaxis (%) | 18.8 | 23.5 | 1.000∗0.772† |
| Frequencies of patient locations (No. of subject, %) | |||
| ED | 12 (75) | 11 (65) | |
| OR | 4 (25) | 7 (41) | |
| ICU | 8 (50) | 12 (71) | |
| WARD | 16 (100) | 17 (100) |
∗ Independent student t test. |
† Fisher exact test. |
Table III. Type of traumatic injury
| No. of subjects (%) | P∗ | ||
|---|---|---|---|
| SCD | CECT | ||
| Head injury | 3 (19) | 3 (18) | .398 |
| Spinal cord injury | 1 (6) | 1 (6) | |
| Pelvic injury | 4 (25) | 1 (6) | |
| Lower-extremity injury | 1 (6) | 5 (29) | |
| Chest injury | 1 (6) | 3 (18) | |
| Abdominal injury | 3 (19) | 1 (6) | |
| Others | 3 (19) | 3 (18) | |
∗ Fisher exact test. |
Compliance rates
Total compliance rate in the CECT group was significantly higher than in the SCD group (P = .004, Table IV). It was also significantly higher in the ED (P = .002) and in the WARD (P = .008). There was a trend toward higher compliance in the OR with the CECT, but this did not reach statistical significance (P = .28). There was no statistically significant difference between the groups in the ICU (P = .99).
Table IV. Compliance rate
| Group | n | Compliance, % | ||||
|---|---|---|---|---|---|---|
| ED (n) | OR (n) | ICU (n) | WARD (n) | Total (N) | ||
| SCD | 16 | 57.8 ± 10.5 (12) | 22.1 ± 22.1 (4) | 69.9 ± 12.5 (8) | 46.0 ± 7.2 (16) | 58.9 ± 4.6 |
| CECT | 17 | 100.0 ± 0.0 (11) | 57.1 ± 20.2 (7) | 70.1 ± 10.8 (12) | 72.8 ± 6.1 (17) | 77.7 ± 3.9 |
| P value | 0.002∗ | 0.28∗ | 0.99∗ | 0.008† | 0.004† | |
∗ Mann-Whitney U test. |
† Independent student t test. |
Discussion
Compliance remains the most significant problem associated with the use of IPC devices for prevention of LEDVT. The devices currently in widespread use require attachment to an external power source to function, and they are frequently not functioning when patients are out of bed or being transported. This problem was first noted by Comerota et al in 1992,13 who reported that patients residing on routine nursing units at their institution were wearing “properly functioning” IPC devices only 48% of the time. More recently Haddad et al14 reported an overall compliance rate of 78% in 79 patients undergoing elective total hip arthroplasties. In 227 trauma patients, Cornwell et al15 reported that IPC devices were applied and functioning only 53% of the time (712 of 1343 observations). Moreover, all three groups stated that education of nursing and other staff did not improve compliance rates.13, 14, 15
Because the amount of time IPC devices are functioning is directly related to the prevalence of LEDVT, compliance is essential. Westrich and Sculco16 studied the efficacy of IPC devices in preventing DVT in 122 patients undergoing total knee replacement. Overall, 27% of patients treated with IPC + aspirin developed LEDVT. However, in patients in whom DVT developed, devices were applied and functioning only 13.4 ± 4.3 hours per day (56% of the time), whereas those in whom no DVT developed were wearing devices 19.2 ± 5.1 hours per day (80% of the time). Interestingly, ward compliance rates reported in the studies of Comerota et al (48%)8 and Cornwell et al (53%),10 as well as the SCD group in this study (59%), are similar to the group in Westrich's11 study in whom DVT occurred. These findings suggest that to achieve LEDVT prevention, compliance rates must be improved. In this study, use of the CECT device resulted in a compliance rate (78%) similar to the group in Westrich's11 study in whom no DVT developed (80%).
Achieving higher compliance rates with IPC will require development of new devices that overcome the limitations of the current generation of devices. These limitations include the requirement for attachment to an external power source and weight, both of which result in discontinuation of pumping when the patient leaves the hospital bed. Even assuming high-quality nursing care, the currently available devices cannot be used when the patient is being transported or is located in areas where power sources are unavailable. Also, they cannot be used when the patient is bathing or ambulating.
By virtue of its design features, the CECT device evaluated in this study eliminates many of the issues contributing to poor compliance rates with pneumatic compression devices. The CECT is small and light (690 g) and is able to operate from a battery for up to 7 hours, which means that it can be in use at virtually all times other than when a patient is bathing. If the patient is transported to a different location, the device can be detached from the power source and the pump will continue to function during transport. Because it weighs very little, patients can carry it, which makes it less likely to be removed when the patient ambulates. Indeed, in this study, significantly higher compliance rates were found with the CECT group (78%) compared with the SCD group (59%).
Compliance rates in the CECT group were also significantly higher than in the SCD group in the ward and in the ED, but not in the ICU. The higher compliance rates observed in the ED with the CECT most likely occurred because patients were transported to radiologic procedures during this period. During transport, the SCD does not operate, whereas the CECT continues to operate from the internal battery. The equivalent compliance observed in the ICU is most likely related to the higher nursing acuity in this location.
There was a trend toward improved compliance in the OR in CECT group, but this did not reach statistical significance. There are two possible explanations for this finding. The first is that the compliance rate with the CECT may truly be higher, but we were unable to demonstrate this because of the small number of patients in this study who underwent operative procedures. Because the SCD device requires attachment to an external power source, staff may forget to turn it on during operative procedures, although the sleeves are applied to the patient. The second is that there may be no difference in compliance rates between the two devices in this environment. Determination of the correct explanation will require a larger study.
Trauma patients were chosen as study subjects in this investigation because of their high risk of DVT and because providing good quality DVT prophylaxis is difficult. Without prophylaxis, patients with major trauma experience DVT at a rate exceeding 50%.17, 18 However, of the two readily available methods of prophylaxis, pneumatic compression devices are frequently impractical and anticoagulants can result in unacceptable bleeding. In one study, anticoagulants were “contraindicated” in 46% of trauma patients.11 Other clinicians have recommended delaying administration of anticoagulants in trauma patients for 24 to 36 hours after injury because of the risk of bleeding.19
These findings demonstrate the difficulty in providing effective DVT prophylaxis during the early period after trauma; yet evidence exists that venous thromboembolism can develop during this period. Owings et al10 studied the timing of the occurrence of pulmonary embolism (PE) in 63 trauma patients, and they found that 6% occurred during the first day of hospitalization, 6% occurred during day 2, and overall 25% occurred during the first 4 days. Reducing the rate of VTE in trauma patients will require a method of prophylaxis that can be initiated in the ED. The data presented here suggest that the CECT device may be the best method in this setting.
Given its ability to improve compliance, the CECT may provide superior DVT prevention compared with that provided by standard devices. However, final proof of the improved efficacy of the CECT will require a larger study in which DVT rates are quantified. Such a study is currently underway in our institution. In the interim, the results of this study also suggest that the CECT device can be used effectively in hospital environments such as the ED where IPC devices have not traditionally been used
Acknowledgements
The authors gratefully acknowledge the technical support of Sarit Gelbart.
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☆ Competition of interest: none.
PII: S0741-5214(03)00792-4
doi:10.1016/S0741-5214(03)00792-4
© 2003 The Society for Vascular Surgery and The American Association for Vascular Surgery. Published by Elsevier Inc. All rights reserved.
