Evaluation of Newer Drug Therapies for Hepatitis C at a Specialty Pharmacy

Garfunkel, Michelle, Hoehn, David, Thompson, Kayleen, Mathews, Kelly, Patel, Sarjit

January 2016

Class of 2016 Abstract / Objectives: To compare the SVR12 rates of newer hepatitis C therapies, approved between November 2013 and December 2014, in patients at Avella Specialty Pharmacy to SVR12 rates from published literature. Insurance coverage rates will be compared to determine a difference among insurances. Methods: Data were collected electronically from patient charts utilizing the existing computer system and manually through chart review. A complete data collection form in excel compiled the collected data and included the SVR12 rates by therapy, and sub-analysis data such as demographic and descriptive variables. Therapies included Harvoni, Olysio + Sovaldi ± Ribavirin (RBV), Viekira Pak ± RBV, or Sovaldi + RBV. Demographic and descriptive variables included gender, medical insurance, hepatitis C genotype, fibrosis score, treatment-experienced, treatment-naïve, and adverse effects. Insurance coverage rates were also collected through a separate electronic report. Results: A total of 578 patients were included in the analysis of SVR12 (mean age = 59, 60% male). There were 50% of patients with genotype 1a, 18% had cirrhosis, and 60% were treatment-naïve. The overall SVR12 rate achieved by patients at Avella was not significantly different from published clinical trials (91% vs 91%, p = 0.75). Data for coverage rates included a total of 6,284 patients and revealed that Medicare had the highest coverage rate (85%) while Medicaid had the lowest (30%). Conclusions: Newer hepatitis C therapies used in a real world setting had similar SVR12 rates to published literature. Medicaid had a lower coverage rate compared to Medicare and commercial insurances while Medicare had the highest coverage rate.

drug therapies

hepatitis C

pharmacy

Prostanoid-mediated Inhibition of IL-6 Trans-Signalling in Pulmonary Arterial Hypertension: a Role for Suppressor of Cytokine Signalling 3?

Durham, Gillian A.

January 2019

Pulmonary arterial hypertension (PAH) is a rare, devastating disease with no cure. Current treatment consists of a cocktail of vasodilators which relieve symptoms of PAH but do not treat the cause. Thus, there is a need for novel drugs that target the underlying pathological causes of PAH. PAH is a multi-factorial, but one key contributor is the pro-inflammatory cytokine IL-6 which stimulates pro-inflammatory and pro-angiogenic signalling mediated by the JAK/STAT pathway. One way in which IL-6 signalling via JAK/STAT is inhibited is via SOCS3 in a type of negative feedback loop whereby IL-6 induces transcription of SOCS3, which then attenuates further JAK/STAT signalling. SOCS3 can also be induced by cAMP. This is interesting as prostanoids, a type of drug used in the treatment of PAH due to its vasodilator effects and the only type to show any efficacy improving the life expectancy of PAH patients, acts by mobilising cAMP. Thus, prostanoid stimulation of cAMP could potentially limit IL-6 signalling via the induction of SOCS3. This is a novel mechanism of prostanoids which has not previously been considered. This study investigated the capability of prostanoids to limit the pro-inflammatory/pro-angiogenic effects of IL-6 that enable PAH to develop. Initial experiments confirmed that vascular endothelial cells responded to prostanoids which increased SOCS3 and limited IL-6 signalling activity. Further experiments utilising SOCS3 KO endothelial cell models demonstrated prostanoid inhibition of IL-6 signalling was due in part to SOCS3. In conclusion, this project has confirmed that prostanoids do limit the pro-inflammatory effects induced by IL-6 and that this is in part due to SOCS3. Although the exact mechanism is yet to be discovered, it will be beneficial in the treatment of PAH as it provides currently unexploited drug targets which can be considered for future PAH therapies. / British Heart Foundation

Pulmonary arterial hypertension

IL-6

JAK/STAT signalling

Endothelial cells

Prostanoids

Drug therapies

The role of SHP2 in metastatic breast cancer

Hao Chen (12447552)

22 April 2022

<p>  </p> <p>Metastatic breast cancer (MBC) is an extremely recalcitrant disease capable of overcoming targeted therapies and evading immune surveillance via the engagement of complicated signaling networks. Resistance to targeted therapies and therapeutic failure of immune checkpoint blockade (ICB) are two major challenges in treating MBC. To survive in the dynamic tumor microenvironment (TME) during metastatic progression, shared signaling nodes are required for MBC cells to regulate the signaling networks efficiently, which are potential multifunctional therapeutic targets. SH2 containing protein tyrosine phosphatase-2 (SHP2) is a druggable oncogenic phosphatase that is a key shared node in both tumor cells and immune cells. How tumor-cell autonomous SHP2 manages its signaling inputs and outputs to facilitate the growth of tumor cells, drug resistance, immunosuppression, and the limited response of ICB in MBC is not fully understood. Herein, we used inducible genetic depletion and two distinct types of pharmacological inhibitors to investigate anti-tumor effects with immune reprogramming during SHP2 targeting. </p> <p>We first focus on the signaling inputs and outputs of SHP2. We find that phosphorylation of SHP2 at Y542 predicts the survival rates of breast cancer patients and their immune profiles. Phosphorylation of SHP2 at Y542 is elevated with differential activation mechanisms under a growth-factor-induced and extracellular matrix (ECM)-rich culture environment. Phosphorylation of SHP2 at Y542 is also elevated in HER2 positive MBC cells upon acquired resistance to the HER2 kinase inhibitor, neratinib. The resistant cells can be targeted by SHP2 inhibitors. SHP2 inhibitors block ERK1/2 and AKT signaling and readily prevented MBC cell growth induced by multiple growth factors. Inhibition of SHP2 also blocks these signaling events generated from the ECM signaling. In fact, the inhibitory effects of SHP2 blockade are actually enhanced in the ECM-rich culture environment. We utilize the <em>in vitro</em> T-cell killing assays and demonstrate that pretreatment of tumor cells with FGF2 and PDGF reduces the cytotoxicity of CD8+ T cells in a SHP2-dependent manner. Both growth factors and ECM-rich culture environment transcriptionally induce PD-L1 via SHP2. SHP2 inhibition balances MAPK signaling and STAT1 signaling, which prevents growth factor-mediated suppression of INF-γ-induced expression of MHC class I. </p> <p>Next, we evaluate the efficacy of SHP2 inhibitors. Blockade of SHP2 in the adjuvant setting decreased pulmonary metastasis <em>in vivo</em> and extended the survival of systemic tumor-bearing mice. Tumor-cell autonomous depletion of SHP2 reduces pulmonary metastasis and relieves exhaustion markers on CD8+ and CD4+ cells. Meanwhile, both systemic SHP2 inhibition and tumor-cell autonomous SHP2 depletion reduce tumor-infiltrated CD4+ T cells and M2-polarized tumor associated macrophages. </p> <p>Finally, we investigate potential combination therapies with SHP2 inhibitors. The combination of SHP2 inhibitors and FGFR-targeted kinase inhibitors synergistically blocks the growth of MBC cells. Pharmacological inhibition SHP2 sensitizes MBC cells growing in the lung to α-PD-L1 antibody treatment via relieving T cell exhaustion induced by ICB. </p> <p>Overall, our findings support the conclusion that MBC cells are capable of simultaneously engaging several survival pathways and immune-suppressive mechanisms via SHP2 in response to multiple growth factors and ECM signaling. Inhibition of SHP2, potentially in combination with other targeted agents and ICB, holds promise for the therapeutic management of MBC.</p>

Pharmacology

Immunology

Cancer

Cancer Cell Biology

metastasis

breast cancer

combination drug therapies

Tumor microenvironment (TME)

receptor tyrosine kinase family

Extracellular matrix

Programmed cell death ligand 1

T cell activation