ALBERT

Description: Abstract 3326 Immune thrombocytopenia (ITP) is a relatively prevalent disease in dogs with significant morbidity and mortality. Canine ITP is clinically analogous to human ITP, with heterogeneity in bleeding manifestations in individuals with similar platelet counts. With a view to ultimately investigate this bleeding heterogeneity, we set out to develop a canine model of ITP. There are currently no existing large animal models of ITP. An induced canine ITP model would be representative of ITP without the confounding co-morbidities seen in clinical cases. Since spontaneous ITP occurs in both dogs and humans, the dog is an ideal translational model. We hypothesized that 2F9, a murine IgG2a monoclonal antibody to the canine platelet glycoprotein GPIIb (a common target of autoantibodies in ITP), would induce predictable dose-dependent thrombocytopenia (TCP) in healthy dogs. 2F9 had not been previously administered in vivo. We produced highly purified 2F9 and αYFA antibodies from the 2F9 hybridoma (gift of David Wilcox, Blood Research Institute, Wisconsin) and an isotype control murine anti-yellow fever antibody (αYFA) hybridoma. A dose titration (2 dogs) and a dose repeatability study (3 dogs) were performed in healthy adult research dogs by repeated intravenous infusion (≤ 6 doses) of 2F9 antibody until a target nadir of 5–30 × 103 platelets/μl was reached. Platelet counts were performed hourly until the platelet count reached the desired nadir range (t=0 hrs), after which complete blood counts were performed at 2, 4, 6, 8, 12, 24 hours, then q 24 hours for 10 days. The following were evaluated throughout the study: physical examination, buccal mucosal bleeding time (BMBT, baseline and t=0 only), serum cytokines and chemokines (INFγ, Interleukin (IL) 2, 6, 7, 8, 10, 15, 18, KC, IP-10, MCP-1, GM-CSF, TNFα; Milliplex CCYTOMAG-90K), fibrinogen, and D-dimers. Specificity of the 2F9 effect was confirmed by IV infusion of the isotype control (αYFA) to 3 dogs at the highest cumulative effective dose of 2F9 (167 μg/kg); all parameters were measured as above (t=0 hrs was one hour after αYFA dosing). Within 2 hours of a median cumulative 2F9 administration of 63 μg/kg (range 50.0–166.6 μg/kg), all dogs developed profound TCP (range 11–28 × 103/μl). Compared to the control group, platelet nadir was significantly lower (median (range): 6 (4–11) × 103/μl vs. 200 (179–209) × 103/μl; p= 0.036) and change in platelet count from baseline to nadir was significantly greater in the 2F9-treated group (median (range): 238 (179–325) × 103/μl vs. 4 (0–10) × 103/μl; p=0.036) (Fig 1); p-values were calculated using the exact Wilcoxon rank-sum test. Platelet nadir was in our target range and platelet count remained 〈 40 × 103/μl in all 2F9-treated dogs for 24 hours. Dosing was predictable: in each dog, after an initial dose of 50 μg/kg 2F9, the second dose needed to reach the target nadir could be accurately calculated from the initial platelet decrease. 2F9-treated dogs developed a range of clinical bleeding from none to petechiae, ecchymoses, melena, and hematuria. At t=0 hrs, BMBT increased 3–8 fold in treated dogs, compared to 〈 2 fold in control dogs. Dogs had no changes in vital signs or demeanor and did not require any transfusion support. The model does not appear pro-thrombotic as fibrinogen and D-dimers were similar over time in 2F9-treated vs. control dogs. 2F9 infusion also generated negligible systemic inflammation, as assessed by white blood cell count and serum cytokine measurement. Unexpectedly, however, serum IL8 tracked faithfully with platelet count, demonstrating that platelets are a major source of serum IL8 in dogs (Fig 2). Although α granules are known to contain IL8, platelets have not been previously described as a significant serum IL8 source. Since IL8 is an important neutrophil chemokine, our finding may illuminate a novel mechanism of platelet-neutrophil cross-talk. In summary, we have developed a novel large animal ITP model that is highly representative of the spontaneous disease. Like naturally-occurring ITP, dogs demonstrate bleeding heterogeneity despite similar platelet counts (data not shown). We expect our model to lead to further insights into bleeding mechanisms in ITP. Ultimately, understanding what factors predispose certain patients to bleed will allow us to exploit these factors therapeutically as novel ITP treatments. Disclosures: No relevant conflicts of interest to declare.

Description: Abstract 2193 In both canine and human patients with Immune Thrombocytopenia (ITP), bleeding risk is challenging to predict, and potentially leads to over-treatment of patients at low risk. Conversely, recent studies have highlighted the risk of thrombosis in ITP during platelet recovery. Given these clinical observations, we hypothesized that in ITP, changes in platelet response to agonists may occur in addition to changes in platelet numbers. In response to dual agonist activation (thrombin and convulxin), a subpopulation of platelets in both humans and dogs develops enhanced procoagulant activity. This subpopulation is termed coated platelets, and differences in individuals' potential to form coated platelets have been correlated with both hemorrhagic and thrombotic outcomes. In this exploratory study, we serially evaluated ex vivo platelet responsiveness to both thrombin and dual agonists (termed coated platelet potential) in a novel canine model of ITP. Dogs (n=4) were infused with a murine monoclonal anti-GPIIb antibody (2F9) in order to model ITP and generate predictable severe thrombocytopenia. Control dogs (n=3) were infused with a control antibody. Platelet count, thrombin responsiveness, and coated platelet potential were measured at baseline, time zero, 6 hours, 24 hours, and every 24hrs thereafter until the platelet count was ≥ baseline for at least two consecutive measures (recovery). Time zero was defined as the time when platelet count first fell to ≤ 30,000/μl following 2F9 infusion, or 1 hour following control antibody infusion. For platelet thrombin responsiveness, a monoclonal antibody to P-selectin was used to determine platelet P-selectin surface expression by flow cytometry after stimulation with graded doses of thrombin. The ED50 Thrombin was defined as the concentration of thrombin required for half-maximal P-selectin expression. Coated platelet potential was defined as the percent of platelets activated to the highly procoagulant state after dual stimulation with thrombin and convulxin, as determined by binding of biotinylated fibrinogen by platelets by flow cytometry. All dogs in the treated group developed severe thrombocytopenia (median=6×103, range=4–11×103 platelets/uL); no dogs in the control group developed thrombocytopenia. All treated dogs had platelet recovery by 240 hours (median=132 hours, range 120–240hours). Of interest, at 6 hours, ED50 Thrombin in the treated group increased nearly twofold (fig 1A) (ratio of median ED50 Thrombin treated/baseline=1.6, range 1.3–2.3), which correlated with a decline in coated platelet potential by nearly half of baseline (fig 1B) (median 52.4% of baseline, range 19.6–61.5%); minimal change from baseline was observed in controls. In both groups, ED50 Thrombin was lower at recovery than baseline (fig 1A) (treated median ED50 Thrombin=71.5% of baseline; control median ED50 Thrombin=67% of baseline). A trend of rising coated platelet potential was also noted as platelets recovered in the treated group. In conclusion, in this exploratory study of a canine model of ITP, we observed dynamic changes in platelet responsiveness. During severe thrombocytopenia, we observed a rise in ED50, indicating a decline in response to thrombin, which correlated with a fall in coated platelet potential. We speculate that this early fall in platelet thrombin response and coated platelet potential could contribute to hemorrhage risk in ITP. As a complement to this finding, in the treated group, there was a rise in coated platelet potential as platelets rebounded and coated platelet potential was slightly greater than baseline at recovery. This is consistent with others' observation that younger platelets are more likely to have coated platelet potential. We also observed a decline in ED50 Thrombin at recovery, not only in the treated dogs, but also control dogs. Thus, at recovery, the decline in ED50 Thrombin was independent of treatment group. However, this may be an artifact of our small sample size. Our observed increase in coated platelet potential during platelet recovery could potentially contribute to the thrombotic tendency of some ITP patients. Future studies are planned to explore the relationship of hemorrhagic and thrombotic risk with platelet thrombin responsiveness and coated platelet potential in this model of ITP and clinical studies of canine and human ITP. Disclosures: No relevant conflicts of interest to declare.