1 / 46

CPET in Differential Diagnosis

CPET in Differential Diagnosis. Gaye ULUBAY, MD, Assoc. Prof. Baskent University Faculty of Medicine Department of Pulmonary Diseases Ankara, Turkey. Pulmonary circulation. Peripheral circulation. VCO 2. CO2 PROD. EXPIRED. O2 FLOW. Creat PO 4. Muscle. Lungs. Heart and blood.

linus
Download Presentation

CPET in Differential Diagnosis

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. CPET in Differential Diagnosis Gaye ULUBAY, MD, Assoc. Prof. Baskent University Faculty of Medicine Department of Pulmonary Diseases Ankara, Turkey

  2. Pulmonary circulation Peripheral circulation VCO2 CO2 PROD EXPIRED O2 FLOW CreatPO4 Muscle Lungs Heart and blood Mitochon INSPIRED PyrLac O2 CONSUM CO2 FLOW VO2 ENERGY • Obstructive • Restrictive • Infiltrative • Chest wall • CAD • Heart failure • Other HD • Anemia • Obesity • Myopathy • Detraining • Occlusive • Autonomic • Dysfunction • PAH • Thromboembolic • 1o & 2oPVD Wasserman K, Hansen FE Principles of Exercise Testing and Interpretation 2005

  3. Determinants of VO2max Atmosphere Lungs:VE,V/Q, Diffusion Heart: Qt, SV, HR, BP Blood (Hb) Skeletal muscle (pump) Peripheral circulation: flow, capillary density, diffusion Muscle: fiber type, mass, mitochondria, O2 extraction, metabolism Johnson & Weisman.Clinical exercise testing, 2003

  4. Why perform CPET ? • To demonstrate exercise limitation • To define cause of exercise limitation • To evaluate preoperatively • To determine morbidity and mortality • To follow up • To evaluate response to treatment

  5. Dyspnea History, physical examination, CBC, Biochemical analysis, chest radiograph, ECG Abnormal; consider spesific diagnostic testing PFT, DLCO, ABG Results are normal BPT or cardiac tests Abnormal Normal Consider spesific diagnostic testing or treatment CPET Abnormal; Consider spesific diagnostic testing, treatment, and follow up normal; close follow-up Zeballos & Weisman.Clinical exercise testing, 2002

  6. CPET parameters • Metabolic VO2, VCO2, R, AT, lactate • Cardiac HR, HRR, ECG, BP, O2 Pulse • Respiratory VE, TV, f, PETO2, PETCO2 • Gas exchange SpO2, VE/VCO2, VE/VO2 • Acid-base pH, PaO2, PaCO2 • Symptom Dyspnea, angina, leg fatique

  7. CPET may fail in the evaluation of early/ mild disease as well as combined diseases

  8. Would, but couldn’t Could, but didn’t

  9. Is there an evidence suggesting a significant involvement of systems (respiratory, cardiovascular, muscle)? ERS Task force Eur Respir J 2007 Wasserman K, Hansen FE Principles of Exercise Testing and Interpretation 2005

  10. Is Peak VO2reduced? Any disorder decreasing exercise capacity Peak VO2 (Panel 3)

  11. Is PeakVO2at rest and exercise? Obesity Peak VO2, VO2-WR (Panel 3)

  12. Is exercise limited by impaired O2 pulse? Heart diseases, peripheral/ PVH anemia, hipoxemia AT,VO2/WR, VCO2/WR,VO2/HR, VE/VCO2 (Panel 2,3,5,6)

  13. Is exercise limited by reduced ventilatory capacity? Lung and chest wall diseases BR,Ventilatory response (Panel 1,7,9) 

  14. Is there a V/Q abnormality? PVD, Heart failure, Lung disease VD/VT,VE/VCO2-AT PETCO2 (Panel 4,6,9)

  15. Poor effort or detraining ? Poor effort or detraining HRR, BR Peak R < 1.0, AT-N Panel (2,5,7,8)

  16. Cardiovascular diseases; Heart F, PAH, CAD • Pulmonary diseases ; COPD, ILD • Obesity • Detraining

  17. Heart Failure

  18. LEFT VENTRICULAR DYSFUNCTION VA/Q mismatching Blood (O2) flow  H+La-  CO2 • ATP production VD/VT  pH Ventilatory requirement Inadequate myocardial contractility Dyspnea Dyspnea, fatique EXERCISE LIMITATION

  19. Heart Failure • VD/VT- • HRR– N/ • WR  • BR -N • VT - • VE –early increase • PECO2/PETCO2 • Peak VO2  • O2 pulse  • VE/VCO2  • HR-VO2 is nonlineer • VO2/WR  • AT/ VO2  • Early metabolic acidosis

  20. Heart Failure • 20 Y, M • Dyspnea at rest and exercise • Nonsmoker • FEV1/FVC= 75 % • FEV1= 70 % • ECHO; EF= 25 %

  21. Chronic Obstructive Lung Disease

  22. COPD ± PULMONARY VASCULARDISEASE Work of breathing  V/Q mismatching Blood flow  ATP  PaO2 VD/VT  Lactate  FEV1 and elastic recoil  pH  VCO2 Ventilatory recruitment  Muscle fatigue  Myopathy Ventilatory capacity  + EXERCISE LIMITATION

  23. COPD • VD/VT- • HRR– N/ • VT -  • WR  • VE -  • PECO2/PETCO2 • Peak VO2  • O2 pulse  • VE/VCO2 –AT  • BR -  • VO2/WR  • AT/ VO2 

  24. Normal VO2 COPD Heart diseases W.R. REST EXERCISE

  25. COPD • 62 Y, M • History of 50 pack-years cigarette smoking • Diagnosis of COPD • FEV1= 0.99L • FEV1/FVC= 60 % • MVV= 44L/min • VE= 42L/min

  26. COPD Control COPD Control • 43 stable patients with COPD and 14 healthy controls • PFTs and CPET were performed • Hyperinflation determined at peak exercise, even no findings at rest Ulubay G, Görek A, Savaş S,Öner Eyüboğlu F. Tuberk Toraks, 2005

  27. Pulmonary Arterial Hypertension

  28. COPD ± PULMONARY VASCULARDISEASE Work of breathing  V/Q mismatching Blood flow  ATP  PaO2 VD/VT  Lactate  FEV1 and elastic recoil  pH  VCO2 Ventilatory recruitment  Muscle fatigue  Myopathy Ventilatory capacity  + EXERCISE LIMITATION

  29. PAH • Peak VO2  • VE -  • O2 pulse  • VE/VCO2 –AT  • VE/VCO2  • VD/VT- • AT VO2  • PETCO2  • PETO2  • BR – N • VT -  • PECO2/PETCO2 • VO2/WR 

  30. PETCO2 PECO2, PECO2/PETCO2 Secondary to increased VD/VT PECO2/PETCO2 Ratio: 4 Groups PECO2: 4 Groups PETCO2: 4 Groups 0.80 35 50 0.75 45 30 0.70 Normal Normal Normal 40 0.65 COPD COPD COPD Ratio 35 25 0.60 HF PETCO2, mm Hg PECO2, mm Hg HF HF 0.55 30 PAH PAH PAH 20 0.50 25 0.45 20 15 0.40 Rest Unloaded AT Peak Rest Unloaded AT Peak Rest Unloaded AT Peak Activity Activity Activity n: 25 COPD, n: 25 LVF, n: 25 PVD patients Hansen JE, Ulubay G, Chow BF, Sun XG, Wasserman K. Chest 2007

  31. 73Y, F Complaint of dyspnea 1998- diagnosis of CREST syndr 2003- RT plus Tamoxifen for breast Ca Nonsmoker 2003- ECHO; PAP= 45mmHg Cpx= Bilateral crackles DLCO= 54 %, DLCO/VA= 58 % MVV= 66 L/min VO2/WR= 5.3 f=54/min Desaturated on test PHT

  32. Interstitial Lung Diseases

  33. INTERSTITIAL LUNG DISEASES Parenchymal destruction /scarring Capillary destruction Pulmonary vascular resistance  Hipoxemia VD/VT  Elastic recoil  Left ventricular filling Work of breathing Ventilatory recruitment  Increased CO requirement Cardiac function  Ventilatory impairment Circulatory impairment EXERCISE LIMITATION

  34. ILD • Peak VO2  • O2 pulse  • VE/VCO2 –AT  • VE/VCO2  • WR  • VO2/WR  • AT/ VO2  • VD/VT- • R-  (50/min) • HRR– / • BR - 

  35. TY 45 F • 45 Y, F • HRCT= diffuse bilateral parenchymal infiltrates • ECG=Normal • FVC =61% • TLC=84% • FEV1=58% • FEV1/FVC= 78 % • MVV = 56 L/min • DLCO = 18 % • f = 65/min • VD/VT 0.31 at rest 0.38 peak exercise

  36. Obesity

  37. Obesity • High O2 cost • Peak VO2 is normal • Peak VO2/ body weight is low • Peak VO2/ height is normal • Normal VD/VT • Low PaO2 at rest that normalizes during exercise

  38. Higher O2 cost than normal at rest and during exercise Obesity Normal VO2 W.R. REST EXERCISE Start exercise Wasserman K, Hansen JE Principles of Exercise Testing and Interpretation. 2005

  39. 45 Y, M • Complaint of exercise limitation • ECG=Normal • FEV1=65% • FEV1/FVC= 78 % • MVV = 140L/min • PVO2 = 126 % • ATVO2 = 70 %

  40. Poor effort/ Detraining

  41. Poor effort/ Detraining • Peak VO2  • HRR • AT determination rare • AT/ VO2 –N • Peak exercise R< 1.0 • WR  • VO2/WR  • BR – N • Caotic breathing pattern

  42. 37Y, M • Complaint of exercise limitation • ECG=Normal • FEV1=105% • FEV1/FVC= 78 % • MVV = 170L/min • PVO2 = 50 % • ATVO2 = undetermined

  43. Normal Pretransplantation Posttransplantation Number of subjects 14 7 7 Age; mean in years (SD) 44  14 44  14 43  14 Sex Male 10 4 5 Female 4 3 2 Body mass index (kg/m2) 24  2 23  3 22  2 Hemoglobin (g/dL) 14  2 15 2 13 1 FEV1 (L/s) 3.12  1.04 4.81  1.09 3.08  0.61 FEV1/FVC (%) 80  6 88  4 78  5 Postoperative duration (mo) - - 19 7 LVEF, mean (SD) - 32  17 57  2 Peak VO2 (L/min) 2,24  0.64 1.11  0.36 1.45  0.33 HR (min) 160  15 120  25 114 41 MVV-VE max (L/min) 14 18 24 VE (L/min) 42  10 40  10 36  12 O2 pulse (mL/beat) 13.3  3 8.2  2.1 10.6  5.4 AT D etermined 14 2 - Undetermined - 5 7 FACTORS AFFECTING EXERCISE CAPACITY IN HEART TRANSPLANTATION RECIPIENTS Ulubay G. Ulasli SS. Sezgin A, Haberal M Clin Transplantation 2007

  44. Ulubay G. Ulasli SS. Sezgin A, Haberal M Clin Transplantation 2007

  45. Variable HF COPD PVD Obesity ILD Detraining Peak VO2    N   AT  N/ /   N N/ /N HR Variable, N / N N/ mild N/ mild N/mild / N O2 pulse  / N  N   BR N/   N N/ N  VE/VCO2 N/    N N N/  VD/VT    N N N/ PaO2 N Variable  N/ N  SpO2 N Variable N N  

More Related