Design and Rationale of a Randomized, Double-Blind, Placebo-Controlled, Phase 2/3 Study Evaluating Dociparstat in Acute Lung Injury Associated with Severe COVID-19

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Novel coronavirus 2019 disease (COVID-19) is caused by infection with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). Clinical manifestations of COVID-19 range from mild, self-limited respiratory tract illness to severe alveolar damage leading to progressive respiratory failure, multiple organ failure, and death [1‐3]. Approximately 15–20% of COVID-19 patients develop severe symptoms and exhibit systemic hyperinflammation with elevated cytokine levels and lung immune cell infiltration, which may result in acute damage to capillaries and lung epithelia/alveoli [4]. Additional localized pulmonary thrombotic microangiopathy and a low-grade disseminated intravascular coagulopathy (DIC) add to the lung pathology and organ dysfunction, increasing the risk of death [5, 6].

While the use of anticoagulants such as heparins may have potential clinical benefit [7], they come with the risk of major bleeding events [8]. The global health crisis caused by SARS-CoV-2 mandates aggressive development of both preventative vaccines and therapeutic regimens that effectively treat patients. Current efforts to expedite availability of therapeutics with a demonstrated positive risk/benefit profile include repurposing approved drugs or those already in advanced development for other indications. Dociparstat sodium (DSTAT; 2-O, 3-O desulfated heparin) is one such agent that is currently in late-stage development for acute myeloid leukemia. DSTAT is made by selective removal of the 2′-sulfate group from iduronic acid 2-sulfate and the 3′-sulfate group from 3,6 bis-sulfated glucosamine present in unfractionated heparin. Removal of these sulfates is associated with significantly reduced anticoagulant activity while maintaining the known anti-inflammatory activities of heparin [9].

DSTAT inhibits the activity of high mobility group box protein 1 (HMGB1), a cytokine that plays a major role in the pathogenesis of immune disorders. Elevated HMGB1 in serum is strongly associated with clinical severity and mortality in COVID-19 patients [10]. Extracellular HMGB1, released from dying cells or secreted by activated immune cells, interacts with the receptor for advanced glycation end products (RAGE) and Toll-like receptors (TLR), causing the release of proinflammatory cytokines including, but not limited to, interleukin-6 (IL-6), tumor necrosis factor-alpha (TNF-α), monocyte chemoattractant protein-1 (MCP-1), and macrophage inflammatory protein-1 alpha (MIP-1α), all of which are elevated in severe COVID-19 [9, 11‐13].

Infiltration of monocytes and other immune cells into the inflamed lung tissue is also an important pathogenic driver of acute lung injury. In vivo disease models have demonstrated that DSTAT can reduce HMGB1 in bronchoalveolar lavage fluid, decrease immune cell infiltration in lungs, and improve survival [14‐16]. Molecular drivers of these effects likely include DSTAT inhibition of HMGB1 binding to RAGE, inhibition of leukocyte lung infiltration via decreases in MCP-1 expression, and direct blocking of the cell adhesion molecule P-selectin [9, 17, 18].

COVID-19 coagulopathies may be attributed to several mechanisms including aberrant activation of immune cell responses, excessive inflammation, and immunothrombosis. For example, neutrophils are early responders to infection capable of extruding granular and nuclear contents to produce neutrophil extracellular traps (NETs). While NETs are often beneficial in trapping and eliminating pathogens, they can also promote thrombosis and are correlated with intubation and death in COVID-19 [19‐21]. HMGB1 and platelet factor 4 (PF4), which are both significantly elevated in COVID-19 patients, induce formation of NETs and regulate NET degradation. DSTAT inhibition of HMGB1 and PF4 activities may reduce formation of NETs and promote their clearance [9, 22].

A related pathologic feature of COVID-19 is platelet hyperreactivity, which may contribute to NET formation and life-threatening coagulopathies. In severe disease, platelets have increased expression of P-selectin, which promotes the formation of platelet-leukocyte aggregates. These aggregates are associated with platelet hyperreactivity, immunothrombosis, and damage to lung capillaries [23]. Notably, P-selectin neutralization inhibits development of acute lung injury in animal models; DSTAT effectively blocks the binding and cell adhesion activities of P-selectin [9].

Overall, DSTAT inhibits several potentially key molecular drivers of COVID-19 pathology, including HMGB1, PF4, and P-selectin (Fig. 1). DSTAT’s pharmacologic mechanisms hold the potential to reduce both inflammation and coagulopathies, which contribute to the high morbidity and mortality in hospitalized COVID-19-infected patients population requiring supplemental oxygen. This study aims to determine if DSTAT provides added benefit to standard of care in COVID-19 patients at risk of acute lung injury by decreasing their need for ventilatory support and improving overall clinical outcomes.

The COVID-19 pandemic has resulted in an unprecedented need for rapid identification and development of effective therapies. Dociparstat, a molecule poised to initiate a phase 3 pivotal study in another indication, was found to be uniquely suited to address the pathophysiology of severe COVID-19. Steps were immediately undertaken to design and initiate a feasible, comparative trial to demonstrate that DSTAT provides added benefit to standard of care in COVID-19 patients at risk of acute lung injury, importantly decreasing their need for ventilatory support and improving overall outcomes.

However, the size and nature of the pandemic presented a variety of operational and scientific challenges. The overwhelming burden on healthcare providers, shortages of personal protective equipment, and the need to limit patient contact by medical personnel to prevent potential transmission of infection have been important considerations in protocol design.

The complexity of treatments being evaluated during the COVID-19 global pandemic has necessitated flexibility in the allowances of concurrent medications and selection of endpoints being evaluated. As the landscape and COVID-19 knowledge base evolve, concurrent medications that would have normally been excluded because of lack of efficacy and added safety concerns (i.e., hydroxychloroquine) had to be considered as potential standards of care in this patient population, with close monitoring of cardiovascular safety. In addition, prophylaxis for DVT was incorporated into the protocol to accommodate institutional practices for anticoagulation in the setting of COVID-19. The US Food and Drug Administration also required inclusion of additional agents approved in other indications with potential benefit in COVID-19 patients (e.g., immunomodulators including IL-6 inhibitors and IL-6 receptor antagonists). This current DSTAT trial in COVID-19 has taken into account those potential confounders and has attempted to minimize their effect on the outcomes being interrogated by close monitoring of cardiovascular safety in the case of hydroxychloroquine, protocol-specified dose limitations for DVT prophylaxis and an algorithm for evaluation of potential cases of HIT, and the allowance of non-steroid immunomodulatory agents only in the event of mechanical ventilation, a failure endpoint in the trial. The impact of the recent emergency use authorizations for remdesivir and convalescent plasma and positive clinical outcome data with the addition of dexamethasone on the anticipated effect size of DSTAT has yet to be fully assessed but will be evaluated at the completion of the phase 2 portion of the trial. As these evolving therapies are increasing the proportion of patients surviving without the need for mechanical ventilation, the secondary endpoints of this trial (e.g., the time to improvement in the NIAID ordinal score) will become essential in providing a measure of drug effect on recovery. This identical strategy was utilized by the National Institutes of Health (NIH) in the assessment of remdesivir’s activity.

The end goal of this trial is to demonstrate an additive benefit when DSTAT is added to current standard of care therapeutic treatments. The development of new treatments is essential to effectively mitigate the morbidity and mortality in patients by minimizing hospital stays and ensuring the functionality of hospital wards and critical care units.