Platelet substitutes and novel platelet products

Artificial Blood: A Futuristic Dimension of Modern Day Transfusion Sciences

Artificial blood is an innovative concept of transfusion medicine where specifically designed compounds perform the task of transport and delivery of oxygen in the body to replace this function of allogenic human blood transfusion. Several molecules have been developed in the past few decades to achieve this objective and continous refinements are being continuously made in the quest of the ideal blood substitute. Currently, available technology manufactures artificial blood from haemoglobin obtained from outdated human/bovine blood (Haemoglobin Based Oxygen Carriers) or utilizing Perfluorocarbons. These synthetic blood substitutes are advantageous in that they do not require compatibility testing, are free from blood borne infections, have prolonged shelf life and do not require refrigeration. Artificial blood is projected to have a significant impact on the development of medical care in the future. It can complement the current blood products for transfusion and create a stable supply of safe and effective products. It is likely to reduce the requirements of blood transfusions drastically especially in settings of trauma and surgery thereby reducing the reliance on banked donated blood.

Mimicking adhesive functionalities of blood platelets using ligand-decorated liposomes

Platelet transfusion is used for treating a variety of bleeding complications. Natural platelet-based transfusion products have very short storage life (3-7 days) and high risks of biological contamination and side effects. Consequently, there is significant clinical interest in synthetic platelet-mimetic constructs that can promote hemostasis, while allowing convenient large-scale production, easy portability, long storage life, and minimal biological risks. To this end, research efforts are being directed toward particles that can amplify aggregation of activated platelets or can mimic platelet's ability to undergo adhesion to various vascular matrix proteins. Here, we report on a synthetic construct design that combines the mimicry of platelet's shear-dependent adhesion to vWF and shear-independent adhesion to collagen under flow, on a single particle. For this, we have used 150-nm-diameter liposomes as model particles and have decorated their surface simultaneously with vWF-binding and collagen-binding recombinant protein fragments or synthetic peptide motifs. We demonstrate in vitro that these surface-modified liposomes are able to adhere onto vWF surfaces in a shear-dependent fashion and onto collagen surfaces in a shear-independent fashion under flow. Moreover, when the vWF-binding and the collagen-binding were integrated on a single liposomal platform, the resultant heteromultivalent liposomes showed significantly enhanced adhesion to a vWF/collagen mixed surface compared to liposomes bearing vWF-binding or collagen-binding ligands only, as long as the ligand motifs did not spatially interfere with each other. Altogether, our results establish the feasibility of efficiently mimicking platelet's dual adhesion mechanisms on synthetic particles.

Peptide-decorated liposomes promote arrest and aggregation of activated platelets under flow on vascular injury relevant protein surfaces in vitro

Platelet-mimetic synthetic hemostats are highly attractive in transfusion medicine. To this end, past research reports have described particles that either amplify platelet aggregation or mimic platelet adhesion. However, a construct design that effectively combines both functionalities has not been reported. Here we describe the design of a liposomal construct simultaneously surface-decorated with three peptides (a vWF-binding peptide (VBP), a collagen-binding peptide (CBP), and an active platelet clustering cyclic-RGD (cRGD) peptide), that can integrate platelet-mimetic dual hemostatic activities of adhesion and aggregation. We first demonstrate that surface-immobilized cRGD-liposomes are capable of aggregating activated platelets onto themselves. Subsequently, we demonstrate that hetero-multivalent liposomes bearing VBP, CBP, and cRGD, when introduced in flow with ≈ 20,000 activated platelets per microliter, are capable of adhering to vWF/collagen surfaces and promoting the recruitment/aggregation of platelets onto themselves. We envision that optimizing this construct can lead to a highly refined synthetic hemostat design for potential application in transfusion medicine.

HLA Antigens Shed from the Surface of Synthetic or Naturally Occurred Platelet-Derived Microparticles During Storage of Platelet Concentrate

The demand for standard platelet concentrates (PCs) has continued to increase in the recent years. Infusible platelet membranes (IPM) prepared from new or outdated human platelets have been developed as an alternative to standard PCs, with the additional advantage of long shelf life and increased viral safety. Reduction of HLA antigens on the IPM has been assigned as one of the probable advantages of this product. In re-examining this issue, we studied the existence of HLA class I on the surface of IPM microparticles. In comparison we also surveyed HLA expression on the surface of the naturally occurred platelet-derived microparticles (nPMPs) during 7 days storage. Intended for producing IPM, PCs obtained from Iranian blood transfusion organization were lysed; virally inactivated with wet heat in the presence of a heat stabilizer and then sonicated. IPMs were separated using centrifugation and liquid-stored in 4°C. The expression of HLA class I antigens was surveyed using flow cytometry technique. HLA molecules were present on the microparticles. Shedding of HLA antigens was demonstrated from the surface of the both liquid-stored IPM and nPMPs during storage. Storage of IPM in 4°C was accompanied with significant reduction of HLA molecules. It seemed that achievement of HLA-free IPM could be impossible unless chloroquine treated platelets were used to prepare these microvesicles.

Polyhemoglobin-fibrinogen: a novel oxygen carrier with platelet-like properties in a hemodiluted setting

Polyhemoglobin (polyHb) is currently being assessed in phase III trials under various formulations. At present, none contain clotting factors or platelet substitutes to aid in hemostasis. We have prepared a novel blood substitute that is an oxygen carrier with platelet-like activity. This is formed by crosslinking fibrinogen to hemoglobin to form polyhemoglobin-fibrinogen (polyHb-Fg). This was studied and compared to polyHb for its effect on coagulation both in vitro and in vivo. In the in vitro experiments, PolyHb-Fg showed similar clotting times as whole blood, whereas polyHb showed significantly higher clotting times. This result was confirmed in in vivo experiments using an exchange transfusion rat-model. Using PolyHb, exchange transfusion of 80% or more increased the normal clotting time (1-2 mins) to > 10 mins. Partial clots formed with PolyHb did not adhere to the tubing wall. With PolyHb-Fg, a normal clotting time is maintained, even with 98% exchange transfusion.

Artifical Blood

Elimination of unwanted side-effects, especially transfusion-transmitted diseases (HIV and hepatitis) and leucocyte-mediated allosensitisation, is an important goal of modern transfusion medicine. The problems and high cost factor involved in collecting and storing human blood and the pending world-wide shortages are the other driving forces contributing towards the development of blood substitutes. Two major areas of research in this endeavour are haemoglobin-based oxygen carriers (HBOCs) and perfluorochemicals. Even though they do not qualify as perfect red blood cell substitutes, these 'oxygen carrying solutions' have many potential clinical and non clinical usages. These can reach tissues more easily than normal red cells and can deliver oxygen directly. These are not without adverse effects, and extensive clinical trials are being conducted to test their safety and efficacy. New understandings on the mode of action of these products will help to define their utility and application. Only after successful clinical trials can they be used for patient management, after approval by the FDA.

Production of soluble integrin alpha2beta1 heterodimer complex functionally active in vitro and in vivo

Integrin alpha2beta1, which is a membrane protein consisting of noncovalently bound alpha2 and beta1 chains, mediates cell binding to collagen and plays a role in platelet functions. DNAs encoding the chimeric proteins in which the extracellular domains of each alpha2 and beta1 chain was fused to hinge and Fc regions of human IgG(1)gamma chain were cotransfected into CHO cells. Soluble integrin alpha2beta1 (salpha2beta1) in which alpha2 and beta1 chains were covalently bound by disulfide bonds was recovered from the culture supernatant. salpha2beta1 maintained functional characteristics of cell surface alpha2beta1 as indicated by cation-dependent binding to collagen and conformational changes induced by cations or ligand. Intravenously administered salpha2beta1 in rats colocalized with collagen in inflamed microvessels. Moreover, salpha2beta1-conjugated liposome administered intravenously reduced bleeding time of the thrombocytopenic mice. These results indicated that salpha2beta1 has pharmaceutical utilities as an agent for detecting injured vessels and a component of platelet substitute.

Synthesis of RGD analogs as potential vectors for targeted drug delivery

RGD analogs bind to integrin receptors with high affinity and therefore have the potential to be used as vectors for the targeted delivery of pharmaceutical agents to designated sites. Critical to this application is the ability to synthesize RGD analogs with different side chain functional groups that allow for the ready tethering of pharmaceutical agents without sacrificing their affinity for the target receptor significantly. A series of RGD analogs intended to be used as delivery vectors of pharmaceutical agents were prepared and evaluated for their ability to inhibit platelet aggregation by binding to glycoprotein IIb/IIIa. Among them, compound 11 showed the lowest IC50 against platelets activated by ADP. It was found that such RGD analogs could tolerate side chain modification fairly well with various functional groups attached such as amide, amine, ester, protected amine and poly(ethylene glycol). The fact that the compound with a side chain modification of poly(ethylene glycol) retained high affinity for glycoprotein IIb/IIIa (IC50 150 nM) suggests the feasibility of tethering fairly large pharmaceutical agents to such RGD analogs without significant sacrifice of their affinity to the intended receptor.

Novel platelet products, substitutes and alternatives

Despite the many advances in the safety, processing, and storage of conventional 22 degrees C liquid-stored allogeneic platelet concentrates, there still are significant drawbacks to the use of such products. Efforts to overcome these shortcomings have resulted in an array of novel platelet products, substitutes, and alternatives; which are currently at various stages of development. This review summarizes the recent developments in the frozen and cold storage of platelets; their pathogen inactivation; as well as the status of lyophilized platelets, infusible platelet membranes (IPMs), red cells bearing arginine-glycine-aspartic acid (RGD) ligands, fibrinogen-coated albumin microcapsules, and liposome-based agents; as potential alternatives to the use of conventional platelet transfusions. Pre-clinical studies have been encouraging for several of these novel products; however, to date, very few have entered human trials. Nonetheless, with the ongoing development of diverse products, those properties that may be necessary for their hemostatic effectiveness will become apparent. However, safety and efficacy must be demonstrated in pre-clinical and phase I to III clinical trials before these novel agents, substitutes and alternatives can be used clinically for patients with thrombocytopenia.