Faculty Bibliography

Tacrolimus is highly effective at preventing allograft rejection and prolonging survival after lung transplantation. However, erratic pharmacokinetics may limit efficacy and predispose to greater adverse effects. We conducted a prospective, open-label trial of lung transplant recipients who underwent early conversion (within 30 days) to LCP tacrolimus (LCPT, n = 40) and compared first-year outcomes to an historical control of patients who remained on immediate-release tacrolimus (IRT, n = 24). Subjects were converted 1:1 from IRT to LCPT. The first dose of LCPT overlapped with the last morning dose of IRT. Conversion to LCPT occurred at a median of 17.5 [IQR 12-25] days. The conversion dose ratio was 1.0 mg:mg [IQR 0.75-1.50] at 14 days. At 1 year, there were no differences between LCPT and IRT in the incidence of biopsy-proven (12.5% vs. 25.0%, p = 0.30) or clinically treated (20.0% vs. 25.0%, p = 0.64) acute cellular rejection. However, the severity of any biopsy-proven rejection was significantly higher in the IRT cohort (27.5% vs. 54.2%, p = 0.03). Although not achieving statistical significance, de novo donor-specific antibodies were more commonly observed in the LCPT group (20.0% vs. 4.2%, p = 0.14). Despite this, the incidence of antibody-mediated rejection (7.5% vs. 0.0%, p = 0.29) and early-onset chronic lung allograft dysfunction (7.5% vs. 9.1%, p = 1.00) were similar. The incidence of chronic kidney disease stage 4 or greater at 1-year was similar (7.5% vs. 12.5%, p = 0.66). In conclusion, early conversion to LCPT was feasible and similarly efficacious to IRT in a cohort of lung transplant recipients. Trial Registration: ClinicalTrials.gov identifier: NCT04420195.

Tacrolimus is highly effective at preventing allograft rejection and prolonging survival after lung transplantation. However, erratic pharmacokinetics may limit efficacy and predispose to greater adverse effects. We conducted a prospective, open-label trial of lung transplant recipients who underwent early conversion (within 30 days) to LCP tacrolimus (LCPT, n = 40) and compared first-year outcomes to an historical control of patients who remained on immediate-release tacrolimus (IRT, n = 24). Subjects were converted 1:1 from IRT to LCPT. The first dose of LCPT overlapped with the last morning dose of IRT. Conversion to LCPT occurred at a median of 17.5 [IQR 12-25] days. The conversion dose ratio was 1.0 mg:mg [IQR 0.75-1.50] at 14 days. At 1 year, there were no differences between LCPT and IRT in the incidence of biopsy-proven (12.5% vs. 25.0%, p = 0.30) or clinically treated (20.0% vs. 25.0%, p = 0.64) acute cellular rejection. However, the severity of any biopsy-proven rejection was significantly higher in the IRT cohort (27.5% vs. 54.2%, p = 0.03). Although not achieving statistical significance, de novo donor-specific antibodies were more commonly observed in the LCPT group (20.0% vs. 4.2%, p = 0.14). Despite this, the incidence of antibody-mediated rejection (7.5% vs. 0.0%, p = 0.29) and early-onset chronic lung allograft dysfunction (7.5% vs. 9.1%, p = 1.00) were similar. The incidence of chronic kidney disease stage 4 or greater at 1-year was similar (7.5% vs. 12.5%, p = 0.66). In conclusion, early conversion to LCPT was feasible and similarly efficacious to IRT in a cohort of lung transplant recipients. Trial Registration: ClinicalTrials.gov identifier: NCT04420195.

Human aging presents an evolutionary paradox: while aging rates remain constant, healthspan and lifespan vary widely. We address this conundrum via salutogenesis-the active production of health-through immune resilience (IR), the capacity to resist disease despite aging and inflammation. Analyzing ~17,500 individuals across lifespan stages and inflammatory challenges, we identified a core salutogenic mechanism: IR centered on TCF7, a conserved transcription factor maintaining T-cell stemness and regenerative potential. IR integrates innate and adaptive immunity to counter three aging and mortality drivers: chronic inflammation (inflammaging), immune aging, and cellular senescence. By mitigating these aging mechanisms, IR confers survival advantages: At age 40, individuals with poor IR face a 9.7-fold higher mortality rate-a risk equivalent to that of 55.5-year-olds with optimal IR-resulting in a 15.5-year gap in survival. Optimal IR preserves youthful immune profiles at any age, enhances vaccine responses, and reduces burdens of cardiovascular disease, Alzheimer's, and serious infections. Two key salutogenic evolutionary themes emerge: first, female-predominant IR, including TCF7, likely reflects evolutionary pressures favoring reproductive success and caregiving; second, midlife (40-70 years) is a critical window where optimal IR reduces mortality by 69%. After age 70, mortality rates converge between resilient and non-resilient groups, reflecting biological limits on longevity extension. TNFα-blockers restore salutogenesis pathways, indicating IR delays aging-related processes rather than altering aging rates. By reframing aging as a salutogenic-pathogenic balance, we establish TCF7-centered IR as central to healthy longevity. Targeted midlife interventions to enhance IR offer actionable strategies to maximize healthspan before biological constraints limit benefits.

BACKGROUND:Donor pool expansion is critical as lung candidates suffer high mortality, yet older donor lungs remain underutilized. We evaluated whether accepting an older donor (defined 4 ways: donor age 30-39, 40-49, 50-59, or 60-69 y) lung transplant was associated with a survival benefit over waiting for a younger donor offer. METHODS:Adult candidates who received a lung offer were identified using Scientific Registry of Transplant Recipients data, 2015-2022. Offers were categorized by donor age and candidate lung allocation score (LAS; <40, 40-55, >55). Postoffer mortality was compared between candidates for whom the offer was accepted ("acceptors") versus declined ("decliners") within each age-LAS category using weighted Cox regression. RESULTS:A total of 21 426 candidates received an offer from a donor age ≥30 y; 11 679 accepted. For LAS >55 candidates, a survival benefit was observed for acceptors of donors ages 30-39 y (weighted hazard ratio [wHR] of mortality: 0.450.520.59), 40-49 y (wHR: 0.610.700.79), and 50-59 y (wHR: 0.670.770.88); P < 0.001. For candidates with LAS 40-55, results suggest a survival benefit of accepting lung offers from donors age 30-39 y (wHR: 0.770.870.99) and 40-49 y (wHR: 0.760.870.99); P = 0.03. However, for candidates with LAS <40, a survival benefit was not observed for accepting any older donor transplant, with possible harm in accepting an age 50+ donor offer. CONCLUSIONS:Compared with declining and waiting for a younger donor offer, accepting an older donor lung transplant was associated with a survival advantage in candidates with high LAS in the precontinuous distribution era. Decision makers should consider these findings while recognizing potential changes in waiting time dynamics in the current era.

RATIONALE/BACKGROUND:Lower airway enrichment with oral commensals has been previously associated with grade 3 severe primary graft dysfunction (PGD) after lung transplantation (LT). We aimed to determine whether this dysbiotic signature is present across all PGD severity grades, including milder forms, and whether it is associated with a distinct host inflammatory endotype. METHODS:Lower airway samples from 96 LT recipients with varying degrees of PGD were used to evaluate the lung allograft microbiota via 16S rRNA gene sequencing. Bronchoalveolar lavage (BAL) cytokine concentrations and cell differential percentages were compared across PGD grades. In a subset of samples, we evaluated the lower airway host transcriptome using RNA sequencing methods. RESULTS:Differential analyses demonstrated lower airway enrichment with supraglottic-predominant taxa (SPT) in both moderate and severe PGD. Dirichlet Multinomial Mixtures (DMM) modeling identified two distinct microbial clusters. A greater percentage of subjects with moderate-severe PGD were identified within the dysbiotic cluster (C-SPT) than within the no PGD group (48 and 29%, respectively) though this difference did not reach statistical significance (p=0.06). PGD severity associated with increased BAL neutrophil concentration (p=0.03) and correlated with BAL concentrations of MCP-1/CCL2, IP-10/CXCL10, IL-10, and TNF-α (p<0.05). Furthermore, microbial signatures of dysbiosis correlated with neutrophils, MCP-1/CCL-2, IL-10, and TNF-α (p<0.05). C-SPT exhibited differential expression of TNF, SERPINE1 (PAI-1), MPO, and MMP1 genes and upregulation of MAPK pathways, suggesting that dysbiosis regulates host signaling to promote neutrophilic inflammation. CONCLUSIONS:Lower airway dysbiosis within the lung allograft is associated with a neutrophilic inflammatory endotype, an immune profile commonly recognized as the hallmark for PGD pathogenesis. This data highlights a putative role for lower airway microbial dysbiosis in the pathogenesis of this syndrome.

INTRODUCTION/UNASSIGNED:Mounting evidence indicates that an individual's humoral adaptive immune response plays a critical role in the setting of SARS-CoV-2 infection, and that the efficiency of the response correlates with disease severity. The relationship between the adaptive immune dynamics in the lower airways with those in the systemic circulation, and how these relate to an individual's clinical response to SARS-CoV-2 infection, are less understood and are the focus of this study. MATERIAL AND METHODS/UNASSIGNED:We investigated the adaptive immune response to SARS-CoV-2 in paired samples from the lower airways and blood from 27 critically ill patients during the first wave of the pandemic (median time from symptom onset to intubation 11 days). Measurements included clinical outcomes (mortality), bronchoalveolar lavage fluid (BALF) and blood specimen antibody levels, and BALF viral load. RESULTS/UNASSIGNED:While there was heterogeneity in the levels of the SARS-CoV-2-specific antibodies, we unexpectedly found that some BALF specimens displayed higher levels than the paired concurrent plasma samples, despite the known dilutional effects common in BALF samples. We found that survivors had higher levels of anti-spike, anti-spike-N-terminal domain and anti-spike-receptor-binding domain IgG antibodies in their BALF (p<0.05), while there was no such association with antibody levels in the systemic circulation. DISCUSSION/UNASSIGNED:Our data highlight the critical role of local adaptive immunity in the airways as a key defence mechanism against primary SARS-CoV-2 infection.