Marstacimab, a tissue factor pathway inhibitor neutralizing antibody, improves coagulation parameters of ex vivo dosed haemophilic blood and plasmas.

INTRODUCTION: Tissue factor pathway inhibitor (TFPI) is an endogenous inhibitor of the extrinsic pathway that negatively regulates thrombin production during coagulation. Under haemophilic conditions, where the intrinsic coagulation pathway is impaired, inhibition of TFPI may improve clotting. AIM: We investigated the ex vivo effects of a human TFPI neutralizing antibody, marstacimab (previously PF-06741086), in coagulation assays including rotational thromboelastometry (ROTEM), thrombin generation assay (TGA) and the dilute prothrombin time (dPT) assay, performed in haemophilic whole blood and plasmas. We compared the effects of marstacimab to the effects of recombinant coagulation factors and investigated the reproducibility of marstacimab in restoring haemostasis by comparing its effect in whole blood collected from the same study participants on differing days. METHODS: Citrated whole blood and plasmas obtained from haemophilia participants were supplemented ex vivo with vehicle, marstacimab, recombinant FVIII (rFVIII) or recombinant factor IX (rFIX) and analysed in ROTEM, TGA and the dPT assay using low tissue factor concentrations to trigger coagulation. RESULTS: Marstacimab induced pro-coagulant responses in ROTEM parameters including reduction in clotting times and increases in angle. Similarly, participant plasmas supplemented with marstacimab exhibited improvements in TGA parameters, including reduced lag times, increased peak thrombin concentrations and reductions in dPT clotting time. Concentrations of marstacimab tested showed activity comparable to addition of rFVIII or rFIX and were reproducible. CONCLUSIONS: These studies show the ex vivo potency of marstacimab in restoring haemostasis in whole blood and plasmas from haemophilia participants and comparability to ex vivo reconstitution with recombination coagulation factors.

Evaluating the thrombin generation profiles of four different rFVIII products in FVIII-deficient plasma using FIXa and FXIa activation.

INTRODUCTION: The thrombin generation assay (TGA) can be used to monitor factor replacement therapy in patients with haemophilia. The TGA assay is typically performed using tissue factor as the reaction activator; however, activating with FIXa or FXIa can enhance assay sensitivity when FVIII < 1%. AIMS: To evaluate the sensitivity of the TGA when FIXa (5 nmol/L) and FXIa (0.22 nmol/L) are used to activate the assay in platelet-poor plasma and to compare these data to the one-stage and chromogenic assays. METHODS: Plasma from 10 severe FVIII-deficient subjects was supplemented with FVIII (0%, 0.1%, 0.4%, 1.2%, 4%, 11% and 33%), using either Novo Eight® , Advate® , Eloctate® , turoctocog alfa pegol or a control standard. The one-stage and chromogenic assays quantified the FVIII levels. The TGA assay was activated using either FIXa or FXIa. RESULTS: Both FIXa- and FXIa-activated TGA were sensitive across FVIII concentrations, with intra-assay coefficient of variation (CV) < 10%. The FXIa-activated assay had 25% CV at the lowest level of FVIII compared to 10% CV with FIXa activation. There were strong correlations between the FIXa- and FXIa-activated TGA tests (R2  = 0.9912) and between the one-stage and chromogenic assays (R2  = 0.9469). However, there were poor relationships between the TGA tests and one-stage and chromogenic assays. CONCLUSIONS: Both FIXa- and FXIa activation results in similar TGA profiles across a FVIII range of 0.1%-33%; however, FIXa activation was more robust at the lowest levels of FVIII compared with FXIa activation.

Peptide Amphiphile Micelles for Vaccine Delivery.

Peptide subunit vaccines enable the specific activation of an immune response without the shortcomings of killed or attenuated pathogens. However, peptide subunit vaccines tend to be less immunogenic than those based on whole organisms. To improve peptide immunogenicity, biomaterials-based platforms have been developed. One such platform, the peptide amphiphile micelle platform, has displayed a unique ability to dramatically improve observed immune responses. Here we describe the design, synthesis, characterization, and application of peptide amphiphile micelles to elicit a robust immune response.

Modular Peptide Amphiphile Micelles Improving an Antibody-Mediated Immune Response to Group A Streptococcus.

Inducing a strong and specific immune response is the hallmark of a successful vaccine. Nanoparticles have emerged as promising vaccine delivery devices to discover and elicit immune responses. Fine-tuning a nanoparticle vaccine to create an immune response with specific antibody and other cellular responses is influenced by many factors such as shape, size, and composition. Peptide amphiphile micelles are a unique biomaterials platform that can function as a modular vaccine delivery system, enabling control over many of these important factors and delivering payloads more efficiently to draining lymph nodes. In this study, the modular properties of peptide amphiphile micelles are utilized to improve an immune response against a Group A Streptococcus B cell antigen (J8). The hydrophobic/hydrophilic interface of peptide amphiphile micelles enabled the precise entrapment of amphiphilic adjuvants which were found to not alter micelle formation or shape. These heterogeneous micelles significantly enhanced murine antibody responses when compared to animals vaccinated with nonadjuvanted micelles or soluble J8 peptide supplemented with a classical adjuvant. The heterogeneous micelle induced antibodies also showed cross-reactivity with wild-type Group A Streptococcus providing evidence that micelle-induced immune responses are capable of identifying their intended pathogenic targets.

Self-assembling peptide-based building blocks in medical applications.

Peptides and peptide-conjugates, comprising natural and synthetic building blocks, are an increasingly popular class of biomaterials. Self-assembled nanostructures based on peptides and peptide-conjugates offer advantages such as precise selectivity and multifunctionality that can address challenges and limitations in the clinic. In this review article, we discuss recent developments in the design and self-assembly of various nanomaterials based on peptides and peptide-conjugates for medical applications, and categorize them into two themes based on the driving forces of molecular self-assembly. First, we present the self-assembled nanostructures driven by the supramolecular interactions between the peptides, with or without the presence of conjugates. The studies where nanoassembly is driven by the interactions between the conjugates of peptide-conjugates are then presented. Particular emphasis is given to in vivo studies focusing on therapeutics, diagnostics, immune modulation and regenerative medicine. Finally, challenges and future perspectives are presented.

Gadolinium-Functionalized Peptide Amphiphile Micelles for Multimodal Imaging of Atherosclerotic Lesions.

The leading causes of morbidity and mortality globally are cardiovascular diseases, and nanomedicine can provide many improvements including disease-specific targeting, early detection, and local delivery of diagnostic agents. To this end, we designed fibrin-binding, peptide amphiphile micelles (PAMs), achieved by incorporating the targeting peptide cysteine-arginine-glutamic acid-lysine-alanine (CREKA), with two types of amphiphilic molecules containing the gadoliniuim (Gd) chelator diethylenetriaminepentaacetic acid (DTPA), DTPA-bis(stearylamide)(Gd), and 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N-[(poly(ethylene glycol) (PEG))-2000]-DTPA(Gd) (DSPE-PEG2000-DTPA(Gd)). The material characteristics of the resulting nanoparticle diagnostic probes, clot-binding properties in vitro, and contrast enhancement and safety for dual, optical imaging-magnetic resonance imaging (MRI) were evaluated in the atherosclerotic mouse model. Transmission electron micrographs showed a homogenous population of spherical micelles for formulations containing DSPE-PEG2000-DTPA(Gd), whereas both spherical and cylindrical micelles were formed upon mixing DTPA-BSA(Gd) and CREKA amphiphiles. Clot-binding assays confirmed DSPE-PEG2000-DTPA(Gd)-based CREKA micelles targeted clots over 8-fold higher than nontargeting (NT) counterpart micelles, whereas no difference was found between CREKA and NT, DTPA-BSA(Gd) micelles. However, in vivo MRI and optical imaging studies of the aortas and hearts showed fibrin specificity was conferred by the peptide ligand without much difference between the nanoparticle formulations or shapes. Biodistribution studies confirmed that all micelles were cleared through both the reticuloendothelial system and renal clearance, and histology showed no signs of necrosis. In summary, these studies demonstrate the successful synthesis, and the molecular imaging capabilities of two types of CREKA-Gd PAMs for atherosclerosis. Moreover, we demonstrate the differences in micelle formulations and shapes and their outcomes in vitro versus in vivo for site-specific, diagnostic strategies, and provide the groundwork for the detection of thrombosis via contrast-enhancing agents and concurrent therapeutic delivery for theranostic applications.

Factor VIII gene variants and inhibitor risk in African American hemophilia A patients.

African American hemophilia A (HA) patients experience a higher incidence of neutralizing anti-factor VIII (FVIII) antibodies ("inhibitors") vis-à-vis white patients. Nonsynonymous single-nucleotide polymorphisms (ns-SNPs) in the F8 gene encoding FVIII-H484, FVIII-E1241, and FVIII-V2238 are more prevalent in African Americans. This study tested the hypothesis that immune responses to these sites provoke inhibitors. Blood samples were obtained from 174 African American and 198 white HA subjects and their F8 gene sequences determined. Major histocompatibility complex class II binding and T-cell recognition of polymorphic sequences were evaluated using quantitative binding assays and HLA-DRB1 tetramers. Peptides corresponding to 4 common ns-SNPs showed limited binding to 11 HLA-DRB1 proteins. CD4 T cells from 22 subjects treated with FVIII products having sequences at residues FVIII-484, 1241, and 2238 differing from those of putative proteins encoded by their F8 genes did not show high-avidity tetramer binding, whereas positive-control staining of tetanus-specific CD4 T cells was routinely successful. African Americans with an intron-22 inversion mutation showed a 2-3 times-higher inhibitor incidence than whites with the same mutation (odds ratio = 2.3 [1.1-5.0, P = .04]), but this did not correlate with any of the ns-SNPs. We conclude that immune responses to "sequence-mismatched" FVIII products are unlikely to contribute appreciably to the inhibitor incidence in African Americans.

Peptide amphiphile micelles self-adjuvant group A streptococcal vaccination.

Delivery system design and adjuvant development are crucially important areas of research for improving vaccines. Peptide amphiphile micelles are a class of biomaterials that have the unique potential to function as both vaccine delivery vehicles and self-adjuvants. In this study, peptide amphiphiles comprised of a group A streptococcus B cell antigen (J8) and a dialkyl hydrophobic moiety (diC16) were synthesized and organized into self-assembled micelles, driven by hydrophobic interactions among the alkyl tails. J8-diC16 formed cylindrical micelles with highly α-helical peptide presented on their surfaces. Both the micelle length and secondary structure were shown to be enhanced by annealing. When injected into mice, J8-diC16 micelles induced a strong IgG1 antibody response that was comparable to soluble J8 peptide supplemented with two classical adjuvants. It was discovered that micelle adjuvanticity requires the antigen be a part of the micelle since separation of J8 and the micelle was insufficient to induce an immune response. Additionally, the diC16 tail appears to be non-immunogenic since it does not stimulate a pathogen recognition receptor whose agonist (Pam3Cys) possesses a very similar chemical structure. The research presented in this paper demonstrates the promise peptide amphiphile micelles have in improving the field of vaccine engineering.