Exercise in Critical Care

Introduction[edit | edit source]

Icu.jpg

Early mobility in the hospital setting is getting more scrutiny and study.  This page on ambulation on a ventilator is broken into four parts: Part I: Background; Part II: Case Reports; Part III: Research Studies; Part IV: Future Direction.


Part I: Background[edit | edit source]

Result of inactivity/ bedrest[edit | edit source]

  • Bed rest: muscles deteriorate[1]
  • Contractures start[2]
  • Reduced perfusion, increased hemodynamic instability, increased risk for ischemia and injury[3]
  • Muscles – sarcomeres shorten, reducing contracting force and strength; slow fibres convert to fast[4]
  • Inflammatory diseases – can cause diaphragmatic contractile dysfunction
  • Unloading/ resting diaphragm = decreased endurance
  • Sensory deprivation – anxiety, depression, disturbed sleep (therefore medicated)
  • Sense of fatigue – leads to self-limitation[5][6]

Critical Illness Neuromyopathy[edit | edit source]

  • Develops during ICU (vs guillain-barré syndrome or myasthenia gravis).
  • Cardinal locomotor sign – proximal weakness, grossly symmetrical scored by an manual muscle testing sum of arm abduction, elbow flexion, wrist extension, hip flexion, knee extension, dorsiflexion, with 0 = no visible contraction, 1 = visible but no movement, 2 = active but not Antigravity, 3 = active, Antigravity, 4 = active, Antigravity and resistance (NOTE: doesn't say how much resistance!), 5 = normal power <48 – significant weakness; may have sensory, golgi tendon reflex, muscle mass loss can be diagnosed with Electromyography(EMG) which shows reduced action potential, and spontaneous activity occurring but noted to not always be feasible.
  • Patients with critical illness neuromyopathy(CINM) – increased days on a vent, longer weaning, immobility[7]

Outcomes of prolonged ventilation[edit | edit source]

  • DVT’s[8], Pneumonia[9]
  • Diaphragm dysfunction[10]
  • Residual weakness[11] (12 months after admission, still have a significant residual weakness - 66% of NV in 6 min walk test)[12]
  • Sensory deficits (Study: vented >28 days: 59% with motor or sensory deficits, 95% with EMG evidence of chronic partial denervation)[13]
  • Increased mortality[14][15] (Study: PMV 98-00 - 1yr mortality 58%, 22% died in hospital, 36% died within 1 yr of d/c, 57% of survivors got off the vent)[16]
  • Discharge location[17] (Study: d/c disposition: 17% home, 35% to rehab, 23% to SNF. Study: >96hrs on vent 45% to SNF, median time to home 7 months 53% had 1 or more re-admits within 12 months[18]
  • Cognitive deficits[19] (Reports of 27% d/c with cognitive deficits); 49% of survivors return to work at 1 yr.[20]

Part II: Case Reports[edit | edit source]


1. Burns JR, Jones FL. Early ambulation of patients requiring ventilatory assistance. Chest. 1975 Oct 1;68(4):608.

In this letter to the editor, the authors acknowledge the problems of bed rest and the problems of ambulating a patient on a respirator and give a brief description of their walker, and their anecdotal impression (developed over 3 years of the program) of facilitated/hastened to wean and minimizing problems of bed rest.[21]

2. Kirshblum SC, Bach JR. Walker modification for ventilator-assisted individuals. Case report. American journal of physical medicine & rehabilitation. 1992 Oct 1;71(5):304-6.

The purpose of this report was to give a report on ambulating a patient using 24-hr non-invasive ventilator support. The patient was a 53 y.o. male with Milroy's disease, respiratory failure, restrictive pulmonary disease, and a history of R mid-lobe pneumonectomy and acute respiratory failure. Before being admitted he could walk <200' and climb 5 or fewer steps before experiencing dyspnea.

He was admitted and intubated, given bilateral chest tubes, treated for pneumonia, and diagnosed with pulmonary fibrosis. He was given a trach at day 52, and 4 months of attempted vent weaning failed. However, he did convert from Intermittent Positive Pressure Ventilation via the trach to IPPV via mouth during the day and nose at night. At 7 months he was transferred to rehab, dependent in all ADL's and only able to take a few steps.

The facility commenced a comprehensive rehab program consisting of diaphragmatic/ glossopharyngeal breathing, biofeedback, and general strength/ mobility/ endurance. As the pt was not able to manoeuvre a wheelchair with all the equipment required, they modified a walker to assist. He was d/c'ed home after 60 days independent in all ADL's and ambulated >400' with the walker with his O2 sats >94%, and eventually returned to work full-time. At the time of the writing, he was still on IPPV for 20 hrs/day with an improved vital capacity (660ml to 1050ml).

Strengths: Presents the possibility of vent-dependent individual regaining functional ability and social roles

Limitations: case study; no criteria for beginning ambulation; no specifics of a rehab program or walker modifications[22]

3. Smith T, Forrest G, Evans G, Johnson RK, Chandler N. The Albany medical college ventilator walker. Archives of physical medicine and rehabilitation. 1996 Dec 1;77(12):1320-1.

The purpose of this report was to describe the design and use of a walker that could accommodate a ventilator and O2 tank. After describing considerations and the construction of the walker, they presented a 69 y.o. female admitted for an elective CABG, complicated by a difficult vent weaning due to obesity, Hemi-diaphragm paralysis, CHF, left lower lung atelectasis, and obstructive airflow secondary to secretions. She received a trach one month after the surgery, and two days later started using the walker two times a day. Over the next week, the PT reported significant improvement in strength and functional mobility. Five months after the initial surgery she could walk without an assistive device or supplemental O2.

Strengths: specifics for walker dimensions

Limitations: case study; no specific criteria for beginning ambulation.[23]

4.Perme CS, Southard RE, Joyce DL, Noon GP, Loebe M. Early mobilization of LVAD recipients who require prolonged mechanical ventilation. Texas Heart Institute Journal. 2006;33(2):130.

The purpose of this case report was to "report our regimen of mobilization with the aid of a portable ventilator, in patients with cardiac cachexia and LVAD implantation. Further, we describe the specific physical therapy interventions used in an LVAD patient who required prolonged mechanical ventilation after device implantation."

The authors generally present their physical therapy evaluation which includes ventilator settings or O2 requirements, their PT interventions (positioning, strengthening and breathing exercises, bed mobility, transfers, gait, and education; with frequency 1x/day 6-7days/wk, 15 minutes - 1 hr), and criteria for termination of PT session (significant drop in LVAD flow, hypotension signs/symptoms, severe/ intolerable dyspnea, O2 level <90%, significant chest pain, extreme fatigue, and request of pt to stop).

Case report: 51 y.o. male with heart failure secondary to dilated cardiomyopathy, and a R lower lobe nodule. Over the next 5 weeks, pt became progressively worse in his cardiac function, developed renal insufficiency and respiratory failure which resulted in him being intubated. He was placed on an LVAD and they resected his right lower lobe, which was further complicated by medical problems requiring continued ventilation. PT was ordered on Day 7 after he failed the first weaning trial. He was given LE strengthening exercises and mobilization (sit EOB, stand, and bed<>chair), and he was progressed to gait training activities around the ICU while on a vent. In his 49 days ICU stays he was vented 48 days and received 25 daily PT sessions (17 LE exercise sessions, 22 EOB sessions, 21 standing sessions, and 18 gait training sessions, 4 of which they used a portable ventilator). The patient improved to a T-collar, ambulation without vent support, and was weaned from the vent. After 6 weeks he had a heart transplant and d/c'ed home.

Strengths: Gave more specifics of PT involvement

Limitations: case study; no specific criteria for beginning ambulation other than that they can take a few steps; unclear as to session length/ consistency or ventilation while ambulating.[24]

Part III: Research Studies[edit | edit source]

1. Bailey P, Thomsen GE, Spuhler VJ, Blair R, Jewkes J, Bezdjian L, Veale K, Rodriquez L, Hopkins RO. Early activity is feasible and safe in respiratory failure patients. Critical care medicine. 2007 Jan 1;35(1):139-45.

In this study, the researchers wanted to know if early activity in critically ill patients was feasible and safe. In this prospective cohort study, the participants' patients in an RICU (n=103) who had been on a vent for >4 days (only exclusion criteria was <4days). Pts had to be neurologically responsive to verbal stimulation, meet specific respiratory conditions (FIO2 <0.7, Positive end-expiratory pressure <11cm H2O), and meet circulatory criteria (absence of orthostatic hypotension and catecholamine drips). Those not meeting all 3 criteria had a trial of activity with close monitoring for adverse events. The activity plan required a PT, RT, RN, critical care technician, 2x/day. Activity events included sitting EOB, standing, ambulating. Adverse events were low and did not require extubation, increased cost, or longer stay. Avg ambulation at d/c was 212’ (69% could ambulate 100' or more); age not a factor in participation. Their conclusion was that early activity is feasible and safe in this population, and is a possible therapy to prevent or treat critical illness-related neuromuscular complications. This study did not have a control group, so they could not say that early activity improves d/c time or long-term outcomes.[25]

2.Thomsen GE, Snow GL, Rodriguez L, Hopkins RO. Patients with respiratory failure increase ambulation after transfer to an intensive care unit where the early activity is a priority. Critical care medicine. 2008 Apr 1;36(4):1119-24.

At the same location as the Bailey study, the researchers hypothesized that "ambulation of patients with acute respiratory failure would increase with transfer to an intensive care unit where the activity is a key component of patient care." Their participants (N=104) were patients who were vented >4 days, did not have a neurological disease that prevented activity (e.g. stroke), were not readmitted to the RICU, and were not terminally ill. Those patients were also required to have been in another hospital ICU for 2 days before being transferred to this unit, and have a stay on their unit of 2 or more days so they could compare activity levels. To start the activity protocol they had to be able to follow commands, have FiO2 <0.7 and positive end-expiratory pressure <11cm H2O, no catecholamine drips and no sign of orthostatic hypotension. During ambulation (yes/no, and how far recorded each time) they would monitor O2 sats and BP. They concluded that transferring a patient who is having acute respiratory failure to their unit significantly improved ambulation, even when taking the underlying pathophysiology into account; that the ICU setting "may contribute unnecessary immobilization throughout the course of acute respiratory failure;" and that sedatives significantly reduce the possibility of ambulation. They also called for further research to determine if ICU immobility affects long-term neuromuscular dysfunction and if early activity in the ICU improves outcomes.[26]

3. Morris PE, Goad A, Thompson C, Taylor K, Harry B, Passmore L, Ross A, Anderson L, Baker S, Sanchez M, Penley L. Early intensive care unit mobility therapy in the treatment of acute respiratory failure. Critical care medicine. 2008 Aug 1;36(8):2238-43.

In this study, the researchers wanted to answer if physical therapy in the intensive care unit provides a benefit (the theory is sound, but there is no data). In a medical intensive care unit, patients who were intubated within the past 48 hours and admitted to the MICU within 72 hours were enrolled. Inclusion criteria were>18 years old and having an ET tube, while exclusion criteria were the inability to walk before their ICU illness (use of AD were allowed), cognitive impairment before the illness (defined as "nonverbal"), immunocompromised/on prednisone before admission, having a neuromuscular disease such as myasthenia gravis, Guillan-Barre or ALS which could impair weaning from the vent, acute stroke, BMI >45, hip fracture, unstable c-spine or a pathological fracture, being on a vent >48 hours before being transferred from another facility, >72 hours for current admittance or transferring from another hospital with > 72-hour stay, a DNR order upon admission, recent hospitalization (30 days), cancer treatment in last 6 months, and re-admit to ICU during this stay.

Interestingly, "it was determined a priori that only patients who survived to a hospital discharge would be included in the outcome analyses based on results of prestudy data that found few patients who died in the ICU achieved sufficient wakefulness to be considered for [PT] before their death. Thus, outcome data were compared for patients in the Usual Care Group with patients in the Protocol group who survived to hospital discharge."

Patients were assigned to the Usual Care group (N=165) or the Protocol group (N=165) with a block design. The UCG included usual treatment (PROM), whereas the PG received four levels of treatment in the protocol (1 - PROM, 2 - PROM, active resistance, sitting, 3 - same as #2 but now sitting EOB, and 4 - same as #3 but adding active transfers and building to ambulation. This protocol was implemented 7d/wk with an RN, a CNA, and a PT. Primary outcomes were the proportion of patients receiving PT in the total number of patients surviving to discharge. Their conclusion was that early mobility was feasible, safe, did not increase costs, and reduced ICU and hospital length of stays for those receiving the protocol.[27]

4.Moodie L, Reeve J, Elkins M. Inspiratory muscle training increases inspiratory muscle strength in patients weaning from mechanical ventilation: a systematic review. Journal of physiotherapy. 2011 Jan 1;57(4):213-21.

In this study, the researchers wanted to answer "Does inspiratory muscle training improve inspiratory muscle strength in adults receiving mechanical ventilation" studies involving 394 participants were included. Heterogeneity within some meta-analyses was high. Random-effects meta-analyses showed that the training significantly improved maximal inspiratory pressure (MD 7 cmH2O, 95% CI 5 to 9), the rapid shallow breathing index (MD 15 breaths/min/l, 95% CI 8 to 23) and weaning success (RR 1.34, 95% CI 1.02 to 1.76).

Although only assessed in individual studies, significant benefits were also reported for the time spent on non-invasive ventilation after weaning (MD 16 hours, 95% CI 13 to 18), length of stay in the intensive care unit (MD 4.5 days, 95% CI 3.6 to 5.4) and length of stay in hospital (MD 4.4 days, 95% CI 3.4 to 5.5). Weaning duration decreased in the subgroup of patients with known weaning difficulty. The other outcomes weren't significantly affected or weren't measured.

Their conclusion was that patients in ICU with Inspiratory muscle training shows reductions in length of stay and the duration of non-invasive ventilatory support after extubation.[28]

Part IV: Future Directions[edit | edit source]

We know that immobility has negative repercussions for the patient and that being on a ventilator has even more negative repercussions.

There are studies to show that PT and ambulation of patients on a ventilator is feasible and safe[29][30][31].

So where do we go from here?

[32]

Address barriers to mobility[edit | edit source]

  • Safety concerns
  • Dislodging lines or tubes
  • Reducing already low oxygenation and hemodynamic parameters (NOTE: the Stiller references and Gosselink reference contain a good flowchart to start with)
  • Sedation (which reduces mentation)
  • Cost
  • Number of workers needed
  • Mobility aids needed (do we need to build our own?)
  • Obesity
  • Time[33][34][35]

Changing a culture[edit | edit source]

Given the cost to the patient being immobilized and on a vent, are addressing the barriers a benefit? Even if it is, it will likely require a culture change - on the unit and in the hospital. So how to do that? Those who have gone before (Hopkins et al) have laid out a path that they believe will help with this culture change:

Stage 1

  • establish a sense of urgency
  • Look at pt at d/c; understand limitations they have and are faced with

Stage 2

  • create a powerful guiding coalition
  • Nurse manager, physician director, and a few influential people who are committed to change

Stage 3

  • Create a vision
  • For your job, what can you do as part of the process of care?[36]

Stage 4

  • Communicate the vision
  • Get the idea to other ICU’s about the importance of early ambulation[29]

Stage 5

  • Empower others to act
  • Being able to share small parts of your job – d/c a line or flush a tube – learn how to work with each other and what each other does[37]

Stage 6

  • Plan and create short-term wins,
  • E.g. as # of admissions increased to RICU, the FTE increased

Stage 7

  • Consolidating improvements, making more change
  • Reporting adherence rates to the desired action

Stage 8

  • Institutionalize new approaches
  • Within the team ("this is how it is done") and outside (respect for and desire to follow the new approach)[38]

References[edit | edit source]

  1. Parry SM, Puthucheary ZA. The impact of extended bed rest on the musculoskeletal system in the critical care environment. Extreme physiology & medicine. 2015 Dec;4(1):1-8.
  2. Knight J, Nigam Y, Jones A. Effects of bedrest 5: the muscles, joints and mobility. Nursing Times. 2019;115(4):54-7.
  3. Bose EL, Hravnak M, Pinsky MR. The interface between monitoring and physiology at the bedside. Critical care clinics. 2015 Jan 1;31(1):1-24.
  4. Chambers MA, Moylan JS, Reid MB. Physical inactivity and muscle weakness in the critically ill. Critical care medicine. 2009 Oct 1;37(10):S337-46.
  5. Winkelman C. Inactivity and inflammation in the critically ill patient. Critical care clinics. 2007 Jan 1;23(1):21-34.
  6. Needham DM. Mobilizing patients in the intensive care unit: improving neuromuscular weakness and physical function. Jama. 2008 Oct 8;300(14):1685-90.
  7. De Jonghe B, Lacherade JC, Durand MC, Sharshar T. Critical illness neuromuscular syndromes. Critical care clinics. 2007 Jan 1;23(1):55-69.
  8. Mouchtouris N, Lang MJ, Barkley K, Barros G, Turpin J, Sweid A, Starke RM, Chalouhi N, Jabbour P, Rosenwasser RH, Tjoumakaris S. Predictors of hospital-associated complications prolonging ICU stay in patients with low-grade aneurysmal subarachnoid hemorrhage. Journal of neurosurgery. 2019 May 3;132(6):1829-35.
  9. Clum SR, Rumbak MJ. Mobilizing the patient in the intensive care unit: the role of early tracheotomy. Critical care clinics. 2007 Jan 1;23(1):71-9.
  10. Moodie L, Reeve J, Elkins M. Inspiratory muscle training increases inspiratory muscle strength in patients weaning from mechanical ventilation: a systematic review. Journal of physiotherapy. 2011 Jan 1;57(4):213-21.
  11. Choi J, Tasota FJ, Hoffman LA. Mobility interventions to improve outcomes in patients undergoing prolonged mechanical ventilation: a review of the literature. Biological research for nursing. 2008 Jul;10(1):21-33.
  12. Herridge MS, Cheung AM, Tansey CM, Matte-Martyn A, Diaz-Granados N, Al-Saidi F, Cooper AB, Guest CB, Mazer CD, Mehta S, Stewart TE. One-year outcomes in survivors of the acute respiratory distress syndrome. New England Journal of Medicine. 2003 Feb 20;348(8):683-93.
  13. Fletcher SN, Kennedy DD, Ghosh IR, Misra VP, Kiff K, Coakley JH, Hinds CJ. Persistent neuromuscular and neurophysiologic abnormalities in long-term survivors of prolonged critical illness. Critical care medicine. 2003 Apr 1;31(4):1012-6.
  14. Nelson JE, Meier DE, Litke A, Natale DA, Siegel RE, Morrison RS. The symptom burden of chronic critical illness. Critical care medicine. 2004 Jul 1;32(7):1527-34.
  15. Cox CE, Carson SS, Holmes GM, Howard A, Carey TS. Increase in tracheostomy for prolonged mechanical ventilation in North Carolina, 1993–2002. Critical care medicine. 2004 Nov 1;32(11):2219-26.
  16. Engoren M, Arslanian-Engoren C, Fenn-Buderer N. Hospital and long-term outcome after tracheostomy for respiratory failure. Chest. 2004 Jan 1;125(1):220-7.
  17. Dowdy DW, Eid MP, Dennison CR, Mendez-Tellez PA, Herridge MS, Guallar E, Pronovost PJ, Needham DM. Quality of life after acute respiratory distress syndrome: a meta-analysis. Intensive care medicine. 2006 Aug 1;32(8):1115-24.
  18. Douglas SL, Daly BJ, Gordon N, Brennan PF. Survival and quality of life: short-term versus long-term ventilator patients. Critical care medicine. 2002 Dec 1;30(12):2655-62.
  19. Davydow DS, Gifford JM, Desai SV, Bienvenu OJ, Needham DM. Depression in general intensive care unit survivors: a systematic review. Intensive care medicine. 2009 May 1;35(5):796-809.
  20. Carson SS. Outcomes of prolonged mechanical ventilation. Current opinion in critical care. 2006 Oct 1;12(5):405-11.
  21. Burns JR, Jones FL. Early ambulation of patients requiring ventilatory assistance. Chest. 1975 Oct 1;68(4):608.
  22. Kirshblum SC, Bach JR. Walker modification for ventilator-assisted individuals. Case report. American journal of physical medicine & rehabilitation. 1992 Oct 1;71(5):304-6.
  23. Smith T, Forrest G, Evans G, Johnson RK, Chandler N. The albany medical college ventilator walker. Archives of physical medicine and rehabilitation. 1996 Dec 1;77(12):1320-1.
  24. Perme CS, Southard RE, Joyce DL, Noon GP, Loebe M. Early mobilization of LVAD recipients who require prolonged mechanical ventilation. Texas Heart Institute Journal. 2006;33(2):130.
  25. Bailey P, Thomsen GE, Spuhler VJ, Blair R, Jewkes J, Bezdjian L, Veale K, Rodriquez L, Hopkins RO. Early activity is feasible and safe in respiratory failure patients. Critical care medicine. 2007 Jan 1;35(1):139-45.
  26. Thomsen GE, Snow GL, Rodriguez L, Hopkins RO. Patients with respiratory failure increase ambulation after transfer to an intensive care unit where early activity is a priority. Critical care medicine. 2008 Apr 1;36(4):1119-24.
  27. Morris PE, Goad A, Thompson C, Taylor K, Harry B, Passmore L, Ross A, Anderson L, Baker S, Sanchez M, Penley L. Early intensive care unit mobility therapy in the treatment of acute respiratory failure. Critical care medicine. 2008 Aug 1;36(8):2238-43.
  28. Moodie L, Reeve J, Elkins M. Inspiratory muscle training increases inspiratory muscle strength in patients weaning from mechanical ventilation: a systematic review. Journal of physiotherapy. 2011 Jan 1;57(4):213-21.
  29. 29.0 29.1 Hashem MD, Nelliot A, Needham DM. Early mobilization and rehabilitation in the ICU: moving back to the future. Respiratory care. 2016 Jul 1;61(7):971-9.
  30. Gosselink R, Bott J, Johnson M, Dean E, Nava S, Norrenberg M, Schönhofer B, Stiller K, Van de Leur H, Vincent JL. Physiotherapy for adult patients with critical illness: recommendations of the European Respiratory Society and European Society of Intensive Care Medicine Task Force on physiotherapy for critically ill patients. Intensive care medicine. 2008 Jul 1;34(7):1188-99.
  31. Chiang LL, Wang LY, Wu CP, Wu HD, Wu YT. Effects of physical training on functional status in patients with prolonged mechanical ventilation. Physical therapy. 2006 Sep 1;86(9):1271-81.
  32. Johns Hopkins Medicine: Early Mobility in the ICU https://www.youtube.com/watch?v=D53gygWRhLM
  33. Morris PE, Herridge MS. Early intensive care unit mobility: future directions. Critical care clinics. 2007 Jan 1;23(1):97-110.
  34. Stiller K. Safety issues that should be considered when mobilizing critically ill patients. Critical care clinics. 2007 Jan 1;23(1):35-53.
  35. Stiller K, Phillips A, Lambert P. The safety of mobilisation and its effect on haemodynamic and respiratory status of intensive care patients. Physiotherapy Theory and Practice. 2004 Jan 1;20(3):175-85.
  36. Stiller K. Physiotherapy in intensive care: an updated systematic review. Chest. 2013 Sep 1;144(3):825-47.
  37. Castro AA, Calil SR, Freitas SA, Oliveira AB, Porto EF. Chest physiotherapy effectiveness to reduce hospitalization and mechanical ventilation length of stay, pulmonary infection rate and mortality in ICU patients. Respiratory medicine. 2013 Jan 1;107(1):68-74.
  38. Hopkins RO, Spuhler VJ, Thomsen GE. Transforming ICU culture to facilitate early mobility. Critical care clinics. 2007 Jan 1;23(1):81-96.