Final Outcomes from a Phase 2 Trial of Posoleucel in Allogeneic Hematopoietic Cell Transplant Recipients.

Allogeneic hematopoietic cell transplantation (allo-HCT) recipients are susceptible to viral infections. We conducted a phase 2 trial evaluating the safety and rate of clinically significant infections (CSIs; viremia requiring treatment or end-organ disease) following infusion of posoleucel, a partially HLA-matched, allogeneic, off-the-shelf, multivirus-specific T cell investigational product for preventing CSIs with adenovirus, BK virus, cytomegalovirus, Epstein-Barr virus, human herpesvirus-6, or JC virus. This open-label trial enrolled high-risk allo-HCT recipients based on receiving grafts from umbilical cord blood, haploidentical, mismatched, or matched unrelated donors; post-HCT lymphocytes <180/mm3; or use of T cell depletion. Posoleucel dosing was initiated within 15-49 days of allo-HCT and subsequently every 14 days for up to seven doses. The primary endpoint was the number of CSIs due to the six target viruses by week 14. Of the 26 patients enrolled just three (12%) had a CSI by week 14, each with a single target virus. In vivo expansion of functional virus-specific T cells detected via interferon-γ ELISpot assay was associated with viral control. Persistence of posoleucel-derived T cell clones for up to 14 weeks after the last infusion was confirmed by T cell receptor deep-sequencing. Five patients (19%) had acute GVHD grade II-IV. No patient experienced cytokine release syndrome. All six deaths were due to relapse or disease progression. High-risk allo-HCT patients who received posoleucel had low rates of CSIs from six targeted viruses. Repeat posoleucel dosing was generally safe and well tolerated and associated with functional immune reconstitution. www.clinicaltrials.gov NCT04693637.

Orthogenomics: an update.

The study of genomics in orthopaedics has considerably lagged behind such study in other medical disciplines. Seminal work from other lines of medical research demonstrates the importance of genomic information in the evolution of personalized medicine. Common techniques for studying genome-phenotype associations include single nucleotide polymorphism, haplotype, and quantitative trait loci analysis. The few genome-based studies in major orthopaedic and related conditions have focused on osteoporosis, osteoarthritis, neuropathy and nerve compression, spinal deformity, trauma and inflammatory response, and pain and analgesia. The nascent field of orthogenomics, newly defined here as the application of genomic study to orthopaedic practice, has produced findings that could affect the practice of orthopaedics. However, more work is required, and the findings must be distilled and harnessed into applicable and achievable steps to improve clinical orthopaedic practice.

Long-term IGF-I exposure decreases autophagy and cell viability.

A reduction in IGF-I signaling has been found to increase lifespan in multiple organisms despite the fact that IGF-I is a trophic factor for many cell types and has been found to have protective effects against multiple forms of damage in acute settings. The increase in longevity seen in response to reduced IGF-I signaling suggests that there may be differences between the acute and chronic impact of IGF-I signaling. We have examined the possibility that long-term stimulation with IGF-I may have a negative impact at the cellular level using quiescent human fibroblasts. We find that fibroblast cells exposed to IGF-I for 14 days have reduced long-term viability as judged by colony forming assays, which is accompanied by an accumulation of senescent cells. In addition we observe an accumulation of cells with depolarized mitochondria and a reduction in autophagy in the long-term IGF-I treated cultures. An examination of mice with reduced IGF-I levels reveals evidence of enhanced autophagy and fibroblast cells derived from these mice have a larger mitochondrial mass relative to controls indicating that changes in mitochondrial turnover occurs in animals with reduced IGF-I. The results indicate that chronic IGF-I stimulation leads to mitochondrial dysfunction and reduced cell viability.