Harmeet Bedi is an Interventional Pulmonologist and Clinical Assistant Professor at Stanford University Medical Center and School of Medicine. His expertise is in minimally invasive techniques used in the diagnosis and treatment of various airway and lung diseases such as lung cancer, benign and malignant airway obstruction, asthma, and pleural diseases. He has specific training in rigid bronchoscopy, airway stent placement, balloon bronchoplasty, endobronchial ultrasound (EBUS) and electromagnetic navigation bronchoscopy, bronchial thermoplasty, intrabronchial valve (IBV) insertion, pleural catheter insertion, and medical thoracoscopy. He also specializes in a variety of tumor ablative therapies including laser therapy, electrocautery, argon plasma coagulation (APC), brachytherapy, photodynamic therapy (PDT), and cryotherapy.
- Interventional Pulmonology
- Pulmonary Disease
- Airway Obstruction (Tracheal and Bronchial)
- Thoracic Oncology
- Lung Nodules
- Lung Cancer
- Pleural Disease
- Lung Transplant Complications
Clinical Assistant Professor, Medicine - Pulmonary, Allergy & Critical Care Medicine
Honors & Awards
Teaching Award, Division of Pulmonary & Critical Care Medicine (2018)
Mentorship Award, Stanford Biodesign Fellowship Program (2018)
Mentorship Award, Stanford Biodesign Fellowship Program (2017)
Boards, Advisory Committees, Professional Organizations
Member, American College of Chest Physicians (2012 - Present)
Member, American Thoracic Society (2012 - Present)
Member, American Association of Bronchology and Interventional Pulmonology (2014 - Present)
Fellowship: Henry Ford Health System Dept of Pulmonary and Critical Care Medicine MI
Board Certification, American Association of Bronchology and Interventional Pulmonology, Interventional Pulmonology (2016)
Board Certification, American Board of Internal Medicine, Critical Care Medicine (2015)
Board Certification, American Board of Internal Medicine, Pulmonary Medicine (2014)
Board Certification, American Board of Internal Medicine, Internal Medicine (2012)
Fellowship, Henry Ford Hospital, Interventional Pulmonology (2016)
Fellowship, Loma Linda University, Pulmonary & Critical Care Medicine (2015)
Residency, Loma Linda University, Internal Medicine (2012)
MD, Government Medical College, Patiala (2007)
- Radiology-pathology Correlation in Recovered COVID-19, Demonstrating Organizing Pneumonia. American journal of respiratory and critical care medicine 2020
Microhemorrhage-associated tissue iron enhances the risk forAspergillus fumigatusinvasion in a mouse model of airway transplantation.
Science translational medicine
2018; 10 (429)
Invasive pulmonary disease due to the moldAspergillus fumigatuscan be life-threatening in lung transplant recipients, but the risk factors remain poorly understood. To study this process, we used a tracheal allograft mouse model that recapitulates large airway changes observed in patients undergoing lung transplantation. We report that microhemorrhage-related iron content may be a major determinant ofA. fumigatusinvasion and, consequently, its virulence. Invasive growth was increased during progressive alloimmune-mediated graft rejection associated with high concentrations of ferric iron in the graft. The role of iron inA. fumigatusinvasive growth was further confirmed by showing that this invasive phenotype was increased in tracheal transplants from donor mice lacking the hemochromatosis gene (Hfe -/- ). The invasive phenotype was also increased in mouse syngrafts treated with topical iron solution and in allograft recipients receiving deferoxamine, a chelator that increases iron bioavailability to the mold. The invasive growth of the iron-intolerantA. fumigatusdouble-knockout mutant (ΔsreA/ΔcccA) was lower than that of the wild-type mold. Alloimmune-mediated microvascular damage and iron overload did not appear to impair the host's immune response. In human lung transplant recipients, positive staining for iron in lung transplant tissue was more commonly seen in endobronchial biopsy sections from transplanted airways than in biopsies from the patients' own airways. Collectively, these data identify iron as a major determinant ofA. fumigatusinvasive growth and a potential target to treat or preventA. fumigatusinfections in lung transplant patients.
View details for PubMedID 29467298
- Foreign Bodies in the Airway: Endoscopic Methods Interventions in Pulmonary Medicine edited by Diaz-Jimenez, J., Rodriquez, A. Springer. 2018; 2nd: 547–569
Innovative use of a Montgomery cannula in the bronchoscopic management of tracheal stenosis and failed tracheostomy decannulation.
Respiratory medicine case reports
2017; 22: 130–32
Endoprosthesis are being used in the everyday clinical practice either as a permanent solution or transient. They can be used in both benign and malignant situations.We report a case in which a temporary Montgomery cannula is used in conjunction with therapeutic bronchoscopy to manage a patient with failed tracheostomy decannulation secondary to a distal complex tracheal stenosis.This innovative use of the Montgomery cannula allowed for successful management of the patient's tracheal stenosis and subsequent tracheostomy tube decannulation.
View details for PubMedID 28794964
View details for PubMedCentralID PMC5547240
A Prediction Model to Help with the Assessment of Adenopathy in Lung Cancer (HAL).
American journal of respiratory and critical care medicine
Estimating the probability of finding N2 or N3 (prN2/3) malignant nodal disease on EBUS-TBNA in patients with non-small cell lung cancer (NSCLC) can facilitate the selection of subsequent management strategies.The goal of this study was to develop a clinical prediction model for estimating the prN2/3.We used the AQuIRE registry to identify patients with NSCLC with clinical radiographic stage T1-3, N0-3, M0 disease that had EBUS-TBNA for staging. The dependent variable was the presence of N2 or N3 disease (vs. N0 or N1) as assessed by EBUS-TBNA. Univariate followed by multivariable logistic regression analysis was used to develop a parsimonious clinical prediction model to estimate prN2/3. External validation was performed using data from three other hospitals.The model derivation cohort (n=633) had a 25% prevalence of malignant N2 or N3 disease. Younger age, central location, adenocarcinoma histology, and higher PET-CT N stage were associated with a higher prN2/3. Area under the ROC curve was 0.85 (95% CI, 0.82-0.89), model fit was acceptable (Hosmer-Lemeshow p=0.62, Brier score 0.125). We externally validated the model in 722 patients. Area under the ROC curve was 0.88 (95% CI, 0.85-0.90). Calibration using the general calibration model method resulted in acceptable goodness of fit (Hosmer-Lemeshow test p=0.54, Brier score 0.132).Our prediction rule can be used to estimate prN2/3 in patients with NSCLC. The model has the potential to facilitate clinical decision making in the staging of NSCLC.
View details for PubMedID 28002683
Bronchoscopist-directed Continuous Propofol Infusion for Targeting Moderate Sedation During Endobronchial Ultrasound Bronchoscopy: A Practical and Effective Protocol.
Journal of bronchology & interventional pulmonology
2015; 22 (3): 226-236
Propofol use for sedation during routine flexible bronchoscopy is expanding. However, there are concerns over propofol's reliability in targeting moderate sedation during more complex and lengthy procedures, such as endobronchial ultrasound (EBUS) bronchoscopy. Its delivery by continuous infusion, which provides a steady sedation effect, may be a practical model for achieving reliable outcomes in this setting.We tested a continuous propofol infusion protocol targeting moderate sedation for EBUS bronchoscopy. A fixed loading rate of 125 mcg/kg/min and initial maintenance rate of 75 mcg/kg/min were used. Sedation assessments were performed every 2.5 minutes. The infusion was adjusted by a nurse under the direction of the bronchoscopist to maintain moderate sedation, normal vital signs, and patient comfort. Prospectively collected data from the first 31 patients using the protocol were analyzed.A mix of EBUS types was performed in a fellowship training environment. Median procedure duration was 51 minutes (interquartile range, 41 to 75 min). Ninety-four percent of total bronchoscopy time was spent in moderate sedation, whereas only 1.9% was occupied by agitation-related delays. Average propofol dose per case was 0.07 mg/kg/min (±0.020), and infusion adjustments were required once every 8 minutes. Sampling goals were met in all patients, and diagnostic and nodal staging accuracies were 90% and 91%, respectively. All tumor specimens sent for genetics were sufficient for analysis. There were no major procedure-related complications.Bronchoscopist-directed continuous propofol infusion is effective and practical for reliably and safely targeting moderate sedation during EBUS bronchoscopy, without sacrificing the breadth and accuracy of the procedure.
View details for DOI 10.1097/LBR.0000000000000187
View details for PubMedID 26165893
Identification of Early Acute Lung Injury at Initial Evaluation in an Acute Care Setting Prior to the Onset of Respiratory Failure
2009; 135 (4): 936-943
Despite being a focus of intensive investigation, acute lung injury (ALI) remains a major cause of morbidity and mortality. However, the current consensus definition impedes identification of patients with ALI before they require mechanical ventilation. To establish a definition of early ALI (EALI), we carried out a prospective cohort study to identify clinical predictors of progression to ALI.Potential cases of EALI were identified by daily screening of chest radiographs (CXRs) for all adult emergency department and new medicine service admissions at Stanford University Hospital.Of 1,935 screened patients with abnormal CXRs, we enrolled 100 patients admitted with bilateral opacities present < 7 days and not due exclusively to left atrial hypertension. A total of 33 of these 100 patients progressed to ALI requiring mechanical ventilation during their hospitalization. Progression to ALI was associated with immunosuppression, the modified Rapid Emergency Medicine Score, airspace opacities beyond the bases, systemic inflammatory response syndrome, and the initial oxygen requirement (> 2 L/min). On multivariate analysis, only an initial oxygen requirement > 2 L/min predicted progression to ALI (odds ratio, 8.1; 95% confidence interval, 2.7 to 24.5). A clinical diagnosis of EALI, defined by hospital admission with bilateral opacities on CXR not exclusively due to left atrial hypertension and an initial oxygen requirement of > 2 L/min, was 73% sensitive and 79% specific for progression to ALI.A new clinical definition of EALI may have value in identifying patients with ALI early in their disease course.
View details for DOI 10.1378/chest.08-2346
View details for Web of Science ID 000265113800012
View details for PubMedID 19188549
View details for PubMedCentralID PMC2758305