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Long Bone Fracture Stabilization in Polytrauma Patients

Published 2000
Citation: J Trauma. 2001 May; 50 (5): 958-67

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Authors

EAST Practice Management Guidelines Work Group

C. Michael Dunham, MD, St. Elizabeth Health Center, Youngstown, Ohio 
Michael J. Bosse, MD, Carolina's Medical Center, Charlotte, North Carolina
Thomas V. Clancy, MD, New Hanover, Wilmington, North Carolina 
Frederic J. Cole, Jr, MD, Eastern Virginia Medical Center, Norfolk, Virginia 
Maxime J.M. Coles, MD, Bridgeport Hospital, Bridgeport, Connecticut 
Thomas Knuth, MD, Blanchfield Army Community Hospital, Fort Campbell, Kentucky 
Fred A. Luchette, MD, University of Cincinnati, Cincinnati, Ohio 
Robert Ostrum, MD, Grant Medical Center, Columbus, Ohio 
Brian Plaisier, MD, Bronson Methodist Hospital, Kalamazoo, Michigan 
Attila Poka, MD, Grant Medical Center, Columbus, Ohio 
Ronald J. Simon, MD, Jacobi Medical Center, Bronx, New York

Address for correspondence:

C. Michael Dunham, MD
St. Elizabeth Hospital Center
1044 Belmont Avenue
Youngstown, Ohio 44501-1790
Phone: 330-480-3907
FAX: 330-480-2070
E-mail: Michael_Dunham@HMIS.ORG

I. Statement of the Problem

The optimal timing for long bone stabilization in polytrauma patients has been debated for the last two decades. Much of the relevant literature focused on long bone fracture as a femoral fracture; however, a substantial portion of published studies include various fractures (tibia, humerus, spine, and/or pelvis). Reported benefits of early long bone stabilization in polytrauma patients include increased patient mobilization by eliminating the need for traction and decreased pulmonary morbidity (fat emboli syndrome, pneumonia, adult respiratory distress syndrome [ARDS]), late septic sequelae, hospital care costs, mortality, hospital length of stay (LOS), ICU LOS, and ventilator days. Some authors suggest that early long bone stabilization in polytrauma patients increases blood loss, fluid administration, and surgical stress, fat embolism and pulmonary complication risks, and mortality. However, others intimate that the pulmonary shunt is similar in those undergoing early or late stabilization, i.e., no worse, no better. There have been additional concerns regarding the timing of long bone stabilization in patients with brain or chest injury. Problems with early fixation of long bones in patients with brain injury include secondary brain injury as a result of hypoxemia , hypotension, and/or complexity of controlling intracranial hypertension, increased mortality, and increased fluid administration which might exacerbate cerebral edema. Early long bone stabilization in patients with pulmonary contusion, multiple rib fractures, or hemopneumothorax is also not advised since there are increased pulmonary complications (ARDS, fat embolism syndrome), especially when intramedullary nailing and reaming are used. However, others indicate that chest injury patients with early intramedullary nailing have similar outcomes compared to later intramedullary nailing or other stabilization techniques, i.e. no worse, no better; and pulmonary contusion patients have similar PaO2/FiO2 and duration of mechanical ventilation, i.e. no worse, no better.

II. Process

A. Identification of References

Literature searches were conducted by committee members using Medline. The subcommittee chair also had the OVID Company perform a literature search using EMBASE. Literature survey parameters included studies written in the English language using human subjects which were published between 1980 and 1998.

Medline MESH Search

  1. (femoral fracture / fractures / fracture fixation) AND (thoracic injuries): 414 articles found; only 12 with potential relevance to long bone injury based on the article title with or without abstract review
  2. (fracture fixation / femoral fractures) AND (head injuries / brain injuries ): 666 articles found; only 18 with potential relevance to long bone injury based on the article title with or without abstract review
  3. (fractures / femoral fractures / fracture fixation) AND (multiple trauma): 378 articles found; only 59 with potential relevance to long bone injury based on the article title with or without abstract review
  4. (femoral fractures / fracture fixation / fractures) AND (respiratory insufficiency / respiratory distress syndrome, adult / respiration); 158 articles found; only 34 with potential relevance to long bone injury based on the article title with or without abstract review

Medline Title Strategy

Additional articles were sought by using the following title searches: 1. timing fixation, 2. delayed fixation, 3. early fixation, 4. early osteosynthesis, 5. immediate fixation, 6. timing fracture:, 7. timing osteosynthesis, 8. fracture: brain, 9. fracture: chest, 10. fem: multipl:, 11. fem: poly:, 12. fracture: thoracic, 13. fracture: multipl:, 14. fracture: poly:, 15. fixation multipl:, 16. fixation poly:, and 17. fracture: head.

Other Medline Literature Search Strategies

The bibliography of the relevant articles mentioned previously was reviewed to find additional potentially appropriate publications.

EMBASE Literature Search Strategies

The OVID Company used EMBASE, a medical literature database distinct from the National Library of Medicine, to perform similar 'MESH' and title searches as described above for the Medline searches. The 'MESH' strategy identified 1,462 potentially relevant articles and the title search method captured 351 such articles.

Inclusion in Evidence Tables

Articles retrieved from the above process were selected for inclusion if they met the following criteria: (a) the blunt trauma mechanism was high-energy, (b) each patient had a long bone injury, (c) each patient had a major non-long bone injury, and (d) there was an early and a late group undergoing fracture stabilization.

B. Quality of the References

The quality assessment instrument applied to the references was developed by the EAST Practice Management Guidelines Committee. Articles were classified as

Class I, II, or III according to the following definitions:

Class I: A randomized clinical trial. There were no Class I articles identified.

Class II: A prospective, noncomparative clinical study or a retrospective analysis based on reliable data.

Class III: A retrospective case series or database review.

III. Recommendations

A. Level I

There is insufficient evidence to support a standard of care on this topic.

B. Level II

  1. Polytrauma patients undergoing long bone stabilization within 48 hours of injury have no improvement in survival when compared to those receiving later stabilization; however, there may be some patients who will have fewer complications . There is no evidence that early stabilization has any detrimental effect. It seems preferable to perform early long bone stabilization in polytrauma patients.
  2. There is no compelling evidence that early long bone stabilization in mild, moderate, or severe brain injured patients either enhances or worsens outcome. The timing of long bone stabilization should be individualized according to the patient's clinical condition.
  3. There is no compelling evidence that early long bone stabilization in patients with chest injury alters outcome. It appears reasonable to individualize the timing of long bone stabilization according to the patient's clinical condition. 

IV. Scientific Foundation

Since the literature describes patients with injuries to the non-long bone body region which includes brain injury, chest injury, or mixed injury (the non-fracture injury is variable), and the clinical problems are often distinct, the scientific evidence is organized accordingly. Each study selected has an early and a late group according to the timing of fracture stabilization following injury. Almost all articles describe a clearly delineated number of hours or days for the timing of stabilization. However, a few only indicate "early" or "late" intervention and are typically excluded from this evaluation (see Evidence Tables). Most investigations demonstrate similar injury severity between the early and late stabilization groups; however, it is clear that the magnitude of injury is different between the two groups in some studies. When the latter exists, those investigations are usually excluded from the final outcome analysis (see Evidence Tables). Most studies indicate that the long bone injury is a femoral fracture; however, several publications include patients with only a tibial, pelvic, humeral, or spinal fracture (see Evidence Tables). Mortality and non-mortality outcomes are evaluated to determine whether the early fracture stabilization group has a similar, beneficial, or detrimental effect relative to the late group (see Evidence Tables). An outcome between the early and late group is considered to be different in a given study when the P value is <.05. A few studies considered and cited in the evidence tables have such severe methodological flaws that they are not included in the final outcome analysis.[1-4]

Mixed Injury Group (divergent non-long bone injuries)

Class II and III studies are combined to provide a more valid and comprehensive understanding of the data results. Polytrauma patients undergoing long bone stabilization within 48 hours of injury have no improvement in survival when compared to those receiving later stabilization,[5-13]  however, there may be a reduction in the number of days of mechanical ventilation,[5] [7] [10-13]  ICU [5-7] [10-14]  or hospital LOS,[5-8] [10] [12-14] incidence of ARDS,[6] [7] [9­-11] [16]  pulmonary complications,[5-7] [14] [16]  pneumonia,[6] [7] [11]  or systemic infection.[5] [10] [11] [13]  The outcome summary is presented in Table 1. In essence, polytrauma patients undergoing long bone stabilization within 48 hours of injury have no improvement in survival when compared to those receiving later stabilization; however, there may be some patients who will have fewer morbidities. There is no evidence that early stabilization has any detrimental effect.

Brain Injury Group

Class II Data:

One study focuses on patients with severe traumatic brain injury[8]  while the other co-mingles those with mild, moderate, or severe traumatic brain injury.[12]  Patients with mild, moderate, or severe brain injury undergoing long bone stabilization within 48 hours of injury have similar rates for mortality,[8] [12]  ICU LOS,[12] mechanical ventilation requirements,[12] and total hospital LOS[8] [12] when compared to those receiving later stabilization. The outcome summary is presented in Table 2. There is no compelling evidence that early long bone stabilization in mild, moderate, or severe brain injured patients either enhances or worsens outcome.

Class III Data:

Four studies address those with severe traumatic brain injury,[17-20]  while three investigations evaluate those with mild, moderate, or severe brain injury.[21-23]  Patients with mild, moderate, or severe brain injury undergoing long bone stabilization within 48 hours of injury have similar rates for mortality,[17] [18] [20-23]  ICU LOS,[17] [20-21]  mechanical ventilation requirements,[20] [21]  total hospital LOS,[17] [20] [21]  CNS outcome,[10] [11] [13]  and adverse CNS event,[18] [20] [21] [23]  ARDS,[23]  pulmonary complications,[23]  pneumonia,[20]  and systemic infection rate,[23]  when compared to those receiving later stabilization. The outcome summary is presented in Table 3. These data support the Class II Data study findings.

Chest Injury Group

Class II Data:

Patients with chest injury undergoing long bone stabilization within 48 hours of injury have similar rates for mortality ,[7] [8] [12]  ARDS,[7]  mechanical ventilation requirements,[7] [12]  ICU LOS,[7] [12]  and total hospital LOS,[7] [8] [12]  when compared to those receiving later stabilization. The outcome summary is presented in Table 4. There is no compelling evidence that early long bone stabilization in patients with chest injury either enhances or worsens outcome.

Class III Data:

Patients with chest injury undergoing long bone stabilization within 48 hours of injury may have a worse ARDS rate,[11] [15]  however, the mortality,[11] [24]  pulmonary complication,[24] [25]  and pneumonia[11]  rates, ventilator days,[11] [24]  and ICU LOS[11] [24] are similar when compared to those receiving later stabilization. The outcome summary is presented in Table V. These data support the Class II Data study findings.

V. Summary

For the past couple of decades, there has been a debate regarding the optimal timing of long bone fracture stabilization in polytrauma patients who may or may not have a brain or chest injury.

Mixed injury group:

Polytrauma patients undergoing long bone stabilization within 48 hours of injury have no improvement in survival when compared to those receiving later stabilization; however, there may be some patients who will have fewer morbidities. There is no evidence that early stabilization has any detrimental effect. It seems preferable to perform early long bone stabilization in polytrauma patients.

Brain injury group:

There is no compelling evidence that early long bone stabilization in mild, moderate, or severe brain injured patients either enhances or worsens outcome. It appears reasonable to individualize the timing of long bone stabilization according to the patient's clinical condition.

Chest injury group:

There is no compelling evidence that early long bone stabilization in patients with chest injury either enhances or worsens outcome. It appears reasonable to individualize the timing of long bone stabilization according to the patient's clinical condition.

VI. Future Investigation

Since there are no Data Class I studies and only 6 (27.3%) of the 22 relevant studies are Data Class II, there is a clear need for large, randomized studies. The following factors should be considered in the design of any future investigation:

Inclusion criteria:

Patients should have similar long bone injury, most likely a femoral fracture; there should be a non-long bone injury Abbreviated Injury Scale (AIS)>2 (possibly AIS>3); a consecutive patient cohort should be used, with clear exclusion criteria for those not entering the study.

Patient characteristics:

Grade of fracture (open [III vs. I/II] vs. closed); location of fracture (proximal, shaft, distal); method of initial long bone stabilization (intramedullary nail [with or without reaming], external fixation, plates and screws); degree of hemodynamic instability in first six hours (grade by blood loss, base deficit, hypotension, etc.); degree of brain injury (mild, moderate, or severe) (grade by best Glasgow Coma Scale [GCS] score in first 6 hours and brain AIS); degree of chest injury (grade by lowest PaO2/FiO2 in first 6 hours and chest AIS).

Subgroups according to timing of long bone stabilization:

(1)<24 hours vs. 25-48 hours vs. >48 hoursOR(2)<48 hours vs. >48 hours.

Delineation of relevant outcome variables:

Mortality rate (hospital vs. 30-day); non-mortality outcomes: strict criteria for outcome variable definitions, e.g., pneumonia, ARDS; a priori ranking as to the importance of the various outcome variables; variables to be considered include ARDS, non-ARDS pulmonary complications, ventilator days, pneumonia, systemic infections, multiple organ failure, hospital and/or professional costs, ICU LOS, total hospital LOS, intraoperative complications (hypotension, hypoxemia), adverse CNS events, and CNS outcome.

References

  1. Bone LB, McNamara K, Shine B, Border J. Mortality in multiple trauma patients with fractures. J Trauma 1994;37:262-264.
  2. Friedl HP, Stocker R, Czermak B, Schmal H, Trentz O. Primary fixation and delayed nailing of long bone fractures in severe trauma. Techniques in Orthopaedics 1996;11:59-66.
  3. Riska EB, von Bonsdorff H, Hakkinen S, Jaroma H, Kiviluoto O, Paavilainen T. Prevention of fat embolism by early internal fixation of fractures in patients with multiple injuries. Injury 1976;8:110­116.
  4. Riska EB, Myllynen P. Fat embolism in patients with multiple injuries. J Trauma 1982; 22:891­894.
  5. Beckman SB, Scholten DJ, Bonnell BW, Bukrey CD. Long bone fractures in the polytrauma patient. The role of early operative fixation. Am Surg 1989;55:356-358.
  6. Bone LB, Johnson KD, Weigelt J, Scheinberg R. Early versus delayed stabilization of femoral fractures: A prospective randomized study. J Bone Joint Surg 1989;71A:336-340.
  7. Charash WE, Fabian TC, Croce MA. Delayed surgical fixation of femur fractures is a risk factor for pulmonary failure independent of thoracic trauma. J Trauma 1994;37:667-672.
  8. Fakhry SM, Rutledge R, Dahners LE, Kessler D. Incidence, management, and outcome of femoral shaft fracture: a statewide population-based analysis of 2805 adult patients in a rural state. J Trauma 1994;37:255-260.
  9. Goris RJA, Gimbrere JSF, van Niekerk JL, Schoots FJ, Booy LH. Early osteosynthesis and prophylactic mechanical ventilation in the multitrauma patient. J Trauma 1982;22:895-903.
  10. Johnson KD, Cadambi A, Seibert GB. Incidence of adult respiratory distress syndrome in patients with multiple musculoskeletal injuries: effect of early operative stabilization of fractures. J Trauma 1985;25:375-384.
  11. Pape HC, Auf'm'Kolk M, Paffrath T, Regel G, Sturm JA, Tscherne H. Primary intramedullary femur fixation in multiple trauma patients with associated lung contusion--a cause of posttraumatic ARDS? J Trauma 1993;34:540-548.
  12. Reynolds MA, Richardson JD, Spain DA, Seligson D, Wilson MA, Miller FB. Is the timing of fracture fixation important for the patient with multiple trauma? Ann Surg 1995;222:470-478.
  13. Seibel R, LaDuca J, Hassett JM, et al. Blunt multiple trauma (ISS 36), femur fracture, and the pulmonary traction-septic state. Ann Surg 1985;202:283-295.
  14. Behrman SW, Fabian TC, Kudsk KA, Taylor JC. Improved outcome with femur fractures: Early vs. delayed fixation. J Trauma 1990;30:792-798.
  15. Boulanger BR, Stephen D, Brenneman FD. Thoracic trauma and early intramedullary nailing of femur fractures: Are we doing harm? J Trauma 1997;43(1):24-28.
  16. Talucci RC, Manning J, Lampard S, Bach A, Carrico CJ. Early intramedullary nailing of femoral shaft fractures: a cause of fat embolism syndrome. Am J Surg 1983;146:107-111.
  17. Hofman PA, Goris RJ. Timing of osteosynthesis of major fractures in patients with severe brain injury. J Trauma 1991;31:261-263.
  18. Martens F, Ectors P. Priorities in the management of polytraumatised patients with head injury: partially resolved problems. Acta Neurochir (Wien) 1988;94:70-73.
  19. Sanker P, Frowein RA, Richard KE. Multiple injuries: coma and fractures of the extremities. Neurosurg Rev 1989;12 Suppl 1:51-54.
  20. Starr AJ, Hunt JL, Chason DP, Reinert CM, Walker J. Treatment of femur fracture with associated head injury. J Orthop Trauma 1998;12(1):38-45.
  21. Jaicks RR, Cohn SM, Moller BA. Early fracture fixation may be deleterious after head injury. J Trauma 1997;42:1-6.
  22. Kotwica Z, Balcewicz L, Jagodzinski Z. Head injuries coexistent with pelvic or lower extremity fractures--early or delayed osteosynthesis. Acta Neurochir (Wien) 1990;102:19-21.
  23. Poole GV, Miller JD, Agnew SG, Griswold JA. Lower extremity fracture fixation in head-injured patients. J Trauma 1992;32:654-659.
  24. Pelias ME, Townsend MC, Flancbaum L. Long bone fractures predispose to pulmonary dysfunction in blunt chest trauma despite early operative fixation. Surgery 1992;111:576-579.
  25. Ziran BH, Le T, Zhou H, Fallon W, Wilber JH. The impact of the quantity of skeletal injury on mortality and pulmonary morbidity. J Trauma 1997;43(6):916-921. 

Tables

Table 1. Mixed Injury Group; Class II and III Data Outcome Summary (12 Studies)

 

Early Group vs. Late Group

 

PATIENTS (N = 1,227)

BETTER

SAME

BENEFIT

Mortality

869 (70.8%)

0 (.0%)

869 (100%)

none

ARDS

516 (42.1%)

238 (46.1%)

278 (53.9%)

potential

Pulmonary complications

473 (38.5%)

317 (67.0%)

156 (33.0%)

potential

Ventilator days

486 (39.6%)

96 (19.8%)

390 (80.2%)

potential

ICU LOS*

706 (57.5%)

96 (13.6%)

610 (86.4%)

potential

Total LOS*

927 (75.6%)

454 (49.0%)

473 (51.0%)

potential

Pneumonia

195 (15.9%)

83 (42.6%)

112 (57.4%)

potential

Systemic infection

325 (26.5%)

172 (52.9%)

153 (47.1%)

potential

Multiple organ failure

56 (4.6%)

0 (.0%)

56 (100%)

none

Hospital cost

83 (6.8%)

0 (.0%)

83 (100%)

none

LOS = length of stay.

Table 2. Brain Injury Group; Class II Data Outcome Summary (2 Studies)

 

Early Group vs. Late Group

 

PATIENTS (N = 192)

BETTER

SAME

BENEFIT

Mortality

192 (100%)

0 (.0%)

192 (100%)

none

Ventilator days

105 (54.7%)

0 (.0%)

105 (100%)

none

ICU LOS*

105 (54.7%)

0 (.0%)

105 (100%)

none

Total LOS*

192 (100%)

0 (.0%)

192 (100%)

none

LOS = length of stay.

Table 3. Brain Injury Group; Class III Data Outcome Summary (7 Studies)

 

Early Group vs. Late Group

 

PATIENTS (N = 336)

BETTER

SAME

BENEFIT

BENEFIT

Mortality

314 (93.5%)

58 (18.5%)

222 (70.7%)

34 (10.8%)

likely none

ARDS

72 (21.4%)

0 (.0%)

72 (100%)

0 (.0%)

none

Pulmonary complications

72 (21.4%)

0 (.0%)

72 (100%)

0 (.0%)

none

Ventilator days

50 (14.9%)

0 (.0%)

50 (100%)

0 (.0%)

none

ICU LOS*

108 (32.1%)

0 (.0%)

50 (46.3%)

58 (53.7%)

potential harm

Total LOS*

108 (32.1%)

0 (.0%)

108 (100%)

0 (.0%)

none

Adverse CNS events

144 (42.9%)

0 (.0%)

144 (100%)

0 (.0%)

none

CNS outcome

191 (56.8%)

0 (.0%)

191 (100%)

0 (.0%)

none

LOS = length of stay.

 

Table 4. Chest Injury Group; Class II Data Outcome Summary (4 Studies)

 

Early Group vs. Late Group

 

PATIENTS (N = 283)

BETTER

SAME

WORSE

BENEFIT

Mortality

283 (100%)

0 (.0%)

283 (100%)

0 (.0%)

none

ARDS

82 (28.9%)

0 (.0%)

82 (100%)

0 (.0%)

none

Ventilator days

187 (66.1%)

0 (.0%)

187 (100%)

0 (.0%)

none

ICU LOS*

187 (66.1%)

0 (.0%)

187 (100%)

0 (.0%)

none

Total LOS*

283 (100%)

0 (.0%)

283 (100%)

0 (.0%)

none

LOS = length of stay.

 

Table 5. Chest Injury Group; Class III Data Outcome Summary (4 Studies)

 

Early Group vs. Late Group

 

PATIENTS (N = 274)

BETTER

SAME

WORSE

BENEFIT

Mortality

132 (48.2%)

0 (.0%)

132 (100%)

0 (.0%)

none

ARDS

133 (48.5%)

0 (.0%)

83 (62.4%)

50 (37.6%)

potential

harm

Pulmonary

complications

141 (51.5%)

59 (41.8%)

82 (58.2%)

0 (.0%)

potential

benefit

Ventilator

days

132 (48.2%)

0 (.0%)

132 (100%)

0 (.0%)

none

ICU LOS*

132 (48.2%)

0 (.0%)

132 (100%)

0 (.0%)

none

Multiple

organ failure

50 (18.2%)

0 (.0%)

50 (100%)

0 (.0%)

none

Pneumonia

50 (18.2%)

0 (.0%)

50 (100%)

0 (.0%)

none

LOS = length of stay.

 

 


EVIDENTIARY TABLE
Must Be Polytrauma and Have An Early and Late Fixation Group
MIXED INJURY PATIENT GROUP (E=early; L=late; G=group); NR=not reported)
AuthorPatient TraitsOutcomesData ClassFindings

Bone et al.[6]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 83; ISS: EG-31.8, LG-31.3

mortality: EG-4.3%, LG-2.7%, P=1.0; ARDS: EG-2.2%, LG-16.2%, P=.04; FES: EG-.0%, LG-5.4%, P=.2; ICU LOS: EG-2.8, LG-7.6, P>.05; total LOS: EG-17.3, LG-26.6, P>.05 ; costs: EG-19,854, LG-32,915, P>.05; pneumonia: EG-2.2%, LG-16.2%, P=.04; pulmonary complications: EG-4.3%, LG-45.9%, P<.001

II

EG same outcome as LG: mortality; FES; ICU LOS; total LOS; costs EG better outcome than LG: ARDS; pneumonia; pulmonary complications EG worse outcome than LG: NR

Johnson et al.[10]

all femoral fractures - no; time of early fixation <48 hrs.; total patients 132; ISS: EG-38.2, LG-38.0

mortality: EG-2.4%, LG-12.2%, P=.05; ARDS: EG-7%, LG-39%, P=<.001; infection: EG-4.8%, LG-24.5%, P=<.001; orthopedic infection: EG20.5%, LG-8.2%, P=.08; ventilator days: EG4.9, LG-11.1, P>.05; ICU LOS: EG-4.9, LG11.1, P>.05; total LOS: EG-31.6, LG-38.3, P>.05; ARDS a ISS, severe head injury, and late fixation

II

EG same outcome as LG: mortality; orthopedic infections; ventilator days; ICU LOS; total LOS EG better outcome than LG: ARDS; infections EG worse outcome than LG: NR

Goris et al.[9]

all femoral fractures - no; time of early fixation <48 hrs.; total patients 58; ISS: EG-37.7, LG-54.6; major chest injury: EG23.9%, LG-75.0%, P=.002

mortality: EG-2.2%, LG-41.7%, P<.001; ARDS: EG-17.4%, LG-75.0%, P<.001; ventilator days (survivors): EG-2.5, LG-10

III

Study is not useful.

Goris et al.[9]

all femoral fractures - no; time of early fixation <48 hrs.; total patients 23; HTI-ISS >50

mortality: EG-8%, LG-50%, P=.05; ARDS: EG15%, LG-80%, P=.003; ventilator days (survivors): EG-2.5, LG-10

III

EG same outcome as LG: mortality EG better outcome than LG: ARDS EG worse outcome than LG: NR

Talucci[16]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 100; ISS: EG-23.2, LG-12.4, P<.001

mortality: NR; ARDS: EG-7%, LG-5%, P=1.0; FES: EG-.0%, LG-11%, P=.01; pulmonary complications (hypoxemia): EG-23%, LG-14%, P=0.3

II

EG same outcome as LG: ARDS, pulmonary complications EG better outcome than LG: FES EG worse outcome than LG: NR

Fakhry[8]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 277; ISS: EG-23, LG-22, P>.05

mortality: EG-3.8%, LG-1.5%, P>.05; total LOS: EG-18.4, LG-29.4, P<.001

II

EG same outcome as LG: mortality EG better outcome than LG: total LOS EG worse outcome than LG: NR

Bone[1]

all femoral fractures - no; time of early fixation <48 hrs.; total patients 1,582; ISS >18

mortality: EG-11.9%, LG-19.3%, P<.001; same mortality (≅60%) in the 121 with ISS >45 (7.6% of all patients)

III

Study is not useful.

Riska[4]

all femoral fractures - no; time of early fixation "early"; injury severity

mortality: ; non-mortality:

III

Study is not useful.

Behrman[14]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 137; ISS: >15

mortality: none reported; pulmonary complications (↑ shunt): EG-28.3%, LG-50.5%, P<.05; ICU LOS (ISS 16-35, n=104): EG = LG; ICU LOS (ISS >35, n=33): EG-3, LG-8, P<.05; total LOS: EG-17.7, LG-25.8, P<.05

III

EG same outcome as LG: ICU LOS (ISS 16-35, n=104) EG better outcome than LG: pulmonary complications; ICU LOS (ISS >35, n=33); total LOS EG worse outcome than LG: NR

Reynolds et al.[12]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 105; ISS: EG-27, LG-34, P<.05; brain AIS: EG1.96, LG-2.36, P<.05

mortality: EG-4.2%, LG-.0%, P>.05; mechanical ventilation: EG-42%, LG-67%, P=.01; ventilator days: EG-7.1, LG-7.1, P=1.0; ICU LOS: EG-10.6, LG-9.4, P>.05; total LOS: EG-14.6, LG-21.9, P=NR; total LOS greater compared to group <24 hours; however, authors indicate "increased total LOS was related to greater degree of critical injury"

II

EG same outcome as LG: mortality; ventilator days; ICU LOS; total LOS EG better outcome than LG: none that are not related to injury severity EG worse outcome than LG: NR

Beckman et al.[5]

all femoral fractures - no; time of early fixation <48 hrs.; total patients 97; ISS: EG-33, LG-31, P>.05

mortality: EG-5.3%, LG-2.8%, P>.05; pulmonary complications (PE, FES, ARDS): EG-.0%, LG-19%, P<.05; infection: EG-21%, LG-37%, P>.05; ventilator days: EG-0, LG-0, P>.05; ICU LOS: EG-3, LG-4, P>>.05; total LOS: EG-20, LG-25, P>.05

III

EG same outcome as LG: mortality; infections; ventilator days; ICU LOS; total LOS EG better outcome than LG: pulmonary complications EG worse outcome than LG: NR

Seibel et al.[13]

all femoral fractures - no; time of early fixation <48 hrs. ("immediate"); total patients 40; ISS: EG-36, LG-37, P>.05

mortality: NR, assume none; bacteremia: EG5%, LG-40%, P=.02; ventilator days: EG-3.4, LG-9.7, P=.006; ICU LOS: EG-7.5, LG-15, P=.01; total LOS: EG-23, LG-45, P<.05

II

EG same outcome as LG: mortality EG better outcome than LG: bacteremia; ventilator days; ICU LOS; total LOS EG worse outcome than LG: NR

Riska et al.[3]

all femoral fractures - no; time of early fixation early; injury severity: none described

mortality: ; non-mortality:

III

Study is not useful.

Pape et al.[11]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 56; ISS: EG-22, LG-26, P>.05; AIS head: EG-1.7, LG-2.5, P<.05; GCS: EG14.8, LG-9.1, P>.05

mortality: EG-<5%, LG-<5%, P>.05; ARDS: EG-<10%, LG-<10%, P>.05; infections: EG9%, LG-17%, P=0.4; MOF: EG-3%, LG-4%, P>.05; pneumonia: EG-3%, LG-22%, P=.07; ventilator days: EG-5, LG-11, P<.05; ICU LOS: EG-8, LG-18, P<.05

III

EG same outcome as LG: mortality; ARDS; infections; MOF; pneumonia EG better outcome than LG: ventilator days; ICU LOS EG worse outcome than LG: NR

Charash

et al.[7]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 56; ISS: EG-25, LG-24, P>.05

mortality: EG-4%, LG-13%, P=0.4; ARDS: EG 0%, LG-13%, P=0.1; pulmonary complications: EG-14%, LG-38%, P=0.1; pneumonia: EG10%, LG-38%, P=.07; ventilator days: EG-2.2, LG-5.8, P>.05; ICU LOS: EG-4.5, LG-8.4, P>.05; total LOS: EG-18, LG-28, P>.05

II

EG same outcome as LG: mortality; ARDS; pulmonary complications; pneumonia; ventilator days; ICU LOS; total LOS EG better outcome than LG: NR EG worse outcome than LG: NR

Boulanger et al.[15]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 66; ISS: EG-26, LG-31, P>.05

ARDS: EG-2%, LG-11%, P>.05

III

EG same outcome as LG: ARDS EG better outcome than LG: NR EG worse outcome than LG: NR

Friedl et al.[2]

all femoral fractures - no; time of early fixation 1-4 days; total patients 55; ISS: EG-21, LG-42, P<.05

mortality: EG-13%, LG-0%, P=0.13; ARDS: EG-25%, LG-0%, P=.01; ARDS (excluding patients transferred with ARDS): EG-8%, LG0%, P>.05

III

Study is not useful.

 
EVIDENTIARY TABLE
Must Be Polytrauma and Have An Early and Late Fixation Group
BRAIN INJURY PATIENT GROUP (E=early; L=late; G=group); NR=not reported)
AuthorPatient TraitsOutcomesData ClassFindings

Fakhry et al. [8]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 87; ISS >15 and brain AIS >3

mortality: EG-8.5%, LG-3.6%, P=0.7; total LOS: EG-27, LG-31, P>.05

II

all have severe brain injury EG same outcome as LG: mortality, total LOS EG better outcome than LG: NR EG worse outcome than LG: NR

Kotwica et al.[22]

all femoral fractures - no; time of early fixation <48 hrs.; total patients 100; ISS: Not given; GCS 1015: EG-47%, LG-49%, P>.05; femur/ pelvic fracture: EG-47%, LG27%, P=.03; "massive brain injury": EG-33%, LG-31%, P>.05

mortality: EG-14%, LG-23%, P=0.3; FES: EG0%, LG-6%, P=0.1; GCS III/IV (90 days): EG27%, LG-21%, P=0.5

III

severe brain injury mixed with moderate and mild EG same outcome as LG: mortality, FES, GCS EG better outcome than LG: NR EG worse outcome than LG: NR

Martens et

al.[18]

all femoral fractures - no; time of early fixation early; total patients 22; ISS: EG-37, LG-35, P>.05; GCS: EG-8, LG-8, P>.05

CNS complications: EG-38%, LG-0%, P=.05; EG with CNS complications (n=5): ISS-49, GCS6; EG without CNS complications (n=8): ISS-29, GCS-10

III

most have severe brain injury EG same outcome as LG: CNS complications EG better outcome than LG: NR EG worse outcome than LG: NR

Jaicks et al.[21]

all femoral fractures - no; time of early fixation <48 hrs.; total patients 33; ISS: EG-25, LG-27, P>.05; GCS: EG-11.6, LG-10.8, P>.05; brain AIS: EG-3.3, LG-3.1, P>.05; femur fractures: EG-53%, LG-36%, P=0.3

mortality: EG-11%, LG-0%, P>.05; ventilator days: EG-6.4, LG-6.5, P>.05; ICU LOS: EG-7.1, LG-8.9, P>.05; total LOS: EG-22, LG-27, P>.05; OR hypotension: EG-16%, LG-7%, P>.05; OR hypoxia: EG-11%, LG-7%, P>.05; CNS complications: EG-16%, LG-15%, P>.05; discharge GCS: EG-13.5, LG-15, P>.05;

III

severe brain injury mixed with moderate and mild EG same outcome as LG: mortality, ventilator days, ICU LOS, total LOS, operative complications, CNS complications, discharge GCS EG better outcome than LG: NR EG worse outcome than LG: NR

Hofman and Goris[17]

all femoral fractures - no; time of early fixation <48 hrs.; total patients 58; ISS: EG-44, LG-36, P<.01; GCS: EG-4.6, LG4.7, P>.05; major fractures: EG-100%, LG53%, P<.01

mortality: EG-13%, LG-47%, P<.02; ICU LOS: EG-19, LG-9, P=.05; total LOS: same for EG & LG; GCS: same for EG & LG, P=.07

III

all have severe brain injury EG same outcome as LG: total LOS, GCS EG better outcome than LG: mortality EG worse outcome than LG: ICU LOS EG worse outcome than LG: NR

Poole et al.[23]

all femoral fractures - no; time of early fixation <48 hrs.; total patients 72; ISS: EG-28, LG-34, P=.06; GCS: EG-12, LG10, P>.05

mortality: EG-4%, LG-0%, P=.2; CNS complications: EG-7%, LG-23%, P=.06; ARDS: EG-4%, LG-8%, P>.05; pulmonary complications: EG-42%, LG-58%, P=.2; FES: EG-2%, LG-4%, P>>.05; systemic infections: same for EG & LG; mechanical ventilation: same % for EG & LG

III

severe brain injury mixed with moderate and mild EG same outcome as LG: mortality, CNS complications, ARDS, pulmonary complications, FES, infections, need for mechanical ventilation EG better outcome than LG: NR EG worse outcome than LG: NR

Bone et al.[1]

all femoral fractures - no; time of early fixation <48 hrs.; total patients 384; all patients had GCS 3-8 and a major fracture

mortality: EG-20%, LG-41%, P<.001

III

all have severe brain injury Study is not useful.

Reynolds et al.[12]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 105; ISS: EG-27, LG-34, P<.05; GCS: EG-13.7, LG-8.6, P<.05; brain AIS: EG-1.96, LG-2.36, P<.05

mortality: EG-4.2%, LG-.0%, P>.05; CNS complications: EG-4%, LG-0%, P>.05; mechanical ventilation: EG-42%, LG-67%, P=.01; ventilator days: EG-7.1, LG-7.1, P=1.0; ICU LOS: EG-10.6, LG-9.4, P>.05; total LOS: EG-14.6, LG-21.9, NS; total LOS greater compared to group <24 hours; however, authors indicate "increased total LOS was related to greater degree of critical injury"

II

severe brain injury mixed with moderate and mild EG same outcome as LG: mortality; ventilator days; ICU LOS; total LOS EG better outcome than LG: none that are not related to injury severity EG worse outcome than LG: NR

Sanker et al.[19]  

all femoral fractures - no; time of early fixation <48 hrs.; total patients 34; GCS 4-8

mortality: EG-59%, LG-12%, P<.01

III

all have severe brain injury EG same outcome as LG: NR EG better outcome than LG: NR EG worse outcome than LG: mortality

Starr et al.[20]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 32; GCS >8: n=15; ISS: EG23, LG-30, P>.05; GCS: EG-14.9, LG-13, P>.05; head CT score: EG-2.0, LG-2.2, P>.05; GCS ≤8: n=17; ISS: EG-32, LG-34, P>.05; GCS: EG-6.2, LG5.6, P>.05; head CT score: EG-2.0, LG-2.6, P>.05

GCS >8: no significant difference (P>.05) between early and late group for mortality, CNS complications, pneumonia, ventilator days, ICU LOS, and total LOS; GCS ≤8: no significant difference (P>.05) between early and late group for mortality, CNS complications, pneumonia, ventilator days, ICU LOS, and total LOS

III

results segregated by severe and non-severe brain injury EG same outcome as LG: mortality, CNS complications, pneumonia, ventilator days, ICU LOS, total LOS EG better outcome than LG: NR EG worse outcome than LG: NR

 
EVIDENTIARY TABLE
Must Be Polytrauma and Have An Early and Late Fixation Group
CHEST INJURY PATIENT GROUP (E=early; L=late; G=group); NR=not reported)
AuthorPatient TraitsOutcomesData ClassFindings

Pelias et al.[24]

all femoral fractures - no; time of early fixation <48 hrs.; total patients 82; ISS: EG-25, LG-27, P>.05

mortality: EG-17%, LG-18%, P>.05; pulmonary complications: EG-28%, LG-29%, P>.05; ventilator days: EG-5, LG-5, P>.05; ICU LOS: EG-7, LG-7, P>.05

III

EG same outcome as LG: mortality, pulmonary complications, ventilator days, ICU LOS EG better outcome than LG: NR EG worse outcome than LG: NR

Pape et al.[11]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 50; ISS: EG-33, LG-32, P>.05; chest AIS: EG-3.3, LG-3.4, P>.05

mortality: EG-21%, LG-4%, P=.09; ARDS: EG 33%, LG-8%, P=.03; infections: EG-13%, LG19%, P>.05; MOF: EG-8%, LG-0%, P>.05; pneumonia: EG-21%, LG-12%, P>.05; ventilator days: EG-10, LG-13, P>.05; ICU LOS: EG-11, LG-17, P>.05

III

EG same outcome as LG: mortality, infections, MOF, pneumonia, ventilator days, ICU LOS EG better outcome than LG: NR EG worse outcome than LG: ARDS

Fakhry et al.[8]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 96; EG and LG have femur fracture and chest AIS >3

mortality: EG-5%, LG-0%, P>.05; total LOS: EG-18, LG-29, P>.05

II

EG same outcome as LG: mortality, total LOS EG better outcome than LG: NR EG worse outcome than LG: NR

Reynolds et al.[12]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 105; ISS: EG-27, LG-34, P<.05; chest AIS: EG2.02, LG-2.07 P>.05; head AIS: EG-1.96, LG2.36, P<.05; chest injuries: EG-42%, LG61%, P=.04; LG has "higher incidence of major pulmonary injuries"

mortality: EG-4.2%, LG-.0%, P>.05; mechanical ventilation: EG-42%, LG-67%, P=.01; ventilator days: EG-7.1, LG-7.1, P=1.0; ICU LOS: EG10.6, LG-9.4, P>.05; total LOS: EG-14.6, LG21.9, P=NR; total LOS greater compared to group <24 hrs.; however, authors indicate "increased total LOS was related to greater degree of critical injury"

II

EG same outcome as LG: mortality; ventilator days; ICU LOS; total LOS EG better outcome than LG: none that are not related to injury severity EG worse outcome than LG: NR

Charash et al.[7]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 82; ISS: EG-27, LG-29, P>.05; chest AIS: EG-3.3, LG-3.4, P>.05; bilateral pulmonary contusions: EG-9%, LG-28%, P=.04; endotracheal intubation during resuscitation: EG24%, LG-71%, P=.01; ISS >28: EG-17%, LG-82%, P<.01

mortality: EG-4%, LG-8%, P>.05; ARDS: EG 4%, LG-8%, P>.05; pulmonary complications: EG-16%, LG-56%, P<.01; pneumonia: EG-14%, LG-48%, P<.01; ventilator days: EG-6, LG-10, P>.05; ICU LOS: EG-9, LG-13, P>.05; total LOS: EG-20, LG-25, P>.05

II

EG same outcome as LG: mortality, ARDS, ventilator days, ICU LOS, total LOS EG better outcome than LG: none that are not related to injury severity EG worse outcome than LG: NR

Ziran et al.[25]

all femoral fractures - no; time of early fixation groups <24 hrs, <48 hrs, <72 hrs, <5 days, or >5 days; total patients 59; patients with chest AIS >3 and extremity AIS >3

pulmonary complications: increased with delays in fracture fixation, odds ratio 3.2, P<.03

III

EG same outcome as LG: NR EG better outcome than LG: pulmonary complications EG worse outcome than LG: NR

Boulanger et al.[15]

all femoral fractures - yes; time of early fixation <48 hrs.; total patients 83; ISS: EG-30, LG-39, P>.05; chest AIS: EG-3.3, LG-3.7, P>.05

ARDS: EG-4%, LG-20%, P>.05

III

EG same outcome as LG: ARDS EG better outcome than LG: NR EG worse outcome than LG: NR

 

 

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