Psychiatric Considerations Regarding Prehospital Administration of Ketamine for Agitation.

Recently, ketamine has seen increased use among emergency medical services in the prehospital setting as a first-line means of chemical restraint for agitated patients. In this case report, we explore an instance in which ketamine administration for nonpsychotic agitation before emergency department (ED) evaluation may have caused unexpected psychotic symptoms leading to a complicated ED course necessitating admission. As ketamine gains widespread use in the prehospital setting, the safety profile deserves reevaluation. In the following report, we review relevant literature and discuss important factors to consider regarding the use of prehospital ketamine, including psychiatric and substance abuse history.

Platelet-like nanoparticles: mimicking shape, flexibility, and surface biology of platelets to target vascular injuries.

Targeted delivery of therapeutic and imaging agents in the vascular compartment represents a significant hurdle in using nanomedicine for treating hemorrhage, thrombosis, and atherosclerosis. While several types of nanoparticles have been developed to meet this goal, their utility is limited by poor circulation, limited margination, and minimal targeting. Platelets have an innate ability to marginate to the vascular wall and specifically interact with vascular injury sites. These platelet functions are mediated by their shape, flexibility, and complex surface interactions. Inspired by this, we report the design and evaluation of nanoparticles that exhibit platelet-like functions including vascular injury site-directed margination, site-specific adhesion, and amplification of injury site-specific aggregation. Our nanoparticles mimic four key attributes of platelets, (i) discoidal morphology, (ii) mechanical flexibility, (iii) biophysically and biochemically mediated aggregation, and (iv) heteromultivalent presentation of ligands that mediate adhesion to both von Willebrand Factor and collagen, as well as specific clustering to activated platelets. Platelet-like nanoparticles (PLNs) exhibit enhanced surface-binding compared to spherical and rigid discoidal counterparts and site-selective adhesive and platelet-aggregatory properties under physiological flow conditions in vitro. In vivo studies in a mouse model demonstrated that PLNs accumulate at the wound site and induce ∼65% reduction in bleeding time, effectively mimicking and improving the hemostatic functions of natural platelets. We show that both the biochemical and biophysical design parameters of PLNs are essential in mimicking platelets and their hemostatic functions. PLNs offer a nanoscale technology that integrates platelet-mimetic biophysical and biochemical properties for potential applications in injectable synthetic hemostats and vascularly targeted payload delivery.

Synthetic approaches to RBC mimicry and oxygen carrier systems.

Whole blood or red blood cell (RBC) transfusions are highly significant, clinically, for blood replacement therapies in traumatic injuries, presurgical conditions, and anemias. However, natural RBC-based products suffer from limited shelf life due to pathological contamination and also present risks of refractoriness, graft-versus-host disease, immunosuppression, and acute lung injury. These issues can be only partially resolved by pathogen reduction technologies, serological blood testing, leukoreduction, and specialized storage; hence, they severely affect the efficacy and safety of the blood products. Consequently, there is a significant interest in synthetic RBC analogues that can mimic its oxygen-transport properties while allowing convenient manufacture, reproducibility, long shelf life, and reduced biological risks. To this end, the current Review provides a comprehensive description and discussion of the various research approaches and current state-of-the-art in synthetically mimicking RBC's oxygen-carrying biochemical properties, as well as the biophysical parameters (shape, size and mechanical modulus) that influence RBCs' hemodynamic transport properties in blood flow.

In vitro and in vivo hemostatic capabilities of a functionally integrated platelet-mimetic liposomal nanoconstruct.

There is significant clinical interest in synthetic platelet substitutes that can mimic platelet's hemostastic functionalities while allowing scale-up, minimal biological contamination, and long shelf-life. To this end, mimicking active platelet's hemostatically relevant matrix-adhesion properties and aggregation properties independently and then integrating them via heteromultivalent ligand decoration on a single synthetic particle can lead to an efficient platelet substitute design. We have recently reported on the feasibility of this approach in vitro, using liposomes as model particles. Building on these studies, here we demonstrate the capability of optimizing the platelet-mimetic properties of our liposomal constructs in vitro via modulating the ligand-decoration densities and ligand ratios. In addition, we demonstrate the enhanced hemostatic efficacy of the functionally-integrated platelet-mimetic constructs in vivo. Liposomes were surface-decorated with collagen- and VWF-binding peptides (CBP and VBP) to mimic platelet adhesion and a fibrinogen-mimetic peptide (FMP) to promote platelet aggregation. Modulation of VBP- and CBP-densities and relative ratios enabled optimizing construct adhesion under varying shear-flow conditions. Modulation of FMP-density enabled enhancement of construct-promoted platelet aggregation. The VBP-, CBP- and FMP-decorations were integrated on a single liposome, and these functionally-integrated constructs showed significantly higher hemostatic efficacy in vivo in a mouse tail-transection model compared to 'adhesion-only' or 'aggregation-only' constructs.

Approaches to synthetic platelet analogs.

Platelet transfusion is routinely used for treating bleeding complications in patients with hematologic or oncologic clotting disorders, chemo/radiotherapy-induced myelosuppression, trauma and surgery. Currently, these transfusions mostly use allogeneic platelet concentrates, while products like lyophilized platelets, cold-stored platelets and infusible platelet membranes are under investigation. These natural platelet-based products pose considerable risks of contamination, resulting in short shelf-life (3-5 days). Recent advances in pathogen reduction technologies have increased shelf-life to ~7 days. Furthermore, natural platelets are short in supply and also cause several biological side effects. Hence, there is significant clinical interest in platelet-mimetic synthetic analogs that can allow long storage-life and minimum side effects. Accordingly, several designs have been studied which decorate synthetic particles with motifs that promote platelet-mimetic adhesion or aggregation. Recent refinement in this design involves combining the adhesion and aggregation functionalities on a single particle platform. Further refinement is being focused on constructing particles that also mimic natural platelet's shape, size and elasticity, to influence margination and wall-interaction. The optimum design of a synthetic platelet analog would require efficient integration of platelet's physico-mechanical properties and biological functionalities. We present a comprehensive review of these approaches and provide our opinion regarding the future directions of this research.