Erythrocyte-based drug delivery systems (EBDDS) usered blood cells, their membranes, or their components to release and deliver pharmaceutical agents throughout the body in a controlled manner.[1] Because red blood cells circulate for long periods of time and are potentially non-immunogenic, they are an attractive vector fordrug delivery via the circulatory system.[1][2][3] Erythrocytes can be used intact as carriers,[3] or alternately empty erythrocyte membranes or nanoscale vesicles derived from erythrocytes may be used.
As early as 1973, it was recognized that red blood cells can be loaded with therapeuticenzymes, in order to avoid a possibleimmune reaction to the enzyme or rapid degradation of the enzyme if injected directly into blood.[4] In humans, red blood cells have a half-life in circulation of 10–15 days before clearance by thelymphoreticular system and exhibit a natural tendency to absorb a variety of drugs.[5] Together, these properties allow forcontrolled release of pharmaceutical products over an extended time, and/or targeting of erythrocyte-destroying cells such asmacrophages in thespleen orliver. One of the earliest proposed applications of EBDDS was inenzyme replacement therapy forGaucher disease, in which lipids accumulate in spleen macrophages; the enzymes not present in this disease could thus be delivered directly to macrophages by red blood cells.[4]
Furthermore, red blood cells are not immunogenic as long as theblood type is compatible with the recipient. This property allows potentially immunogenic substances such asproteins to be safely carried through the bloodstream.
There are several variations on the concept of erythrocytes as drug carriers. In the simplest application, erythrocytes may be simply mixed with a membrane-permeable drug and allowed to equilibrate until the drug has been absorbed viadialysis.[6][7] Alternately, aprodrug may be incubated with the erythrocytes, and enzyme activity within the cells gradually converts the prodrug to its active form, further prolonging delivery.[6] If the drug or prodrug is not membrane-permeable, membrane-permeatingpeptides may be added to permeabilize theplasma membrane of the erythrocytes.[3]
If the therapeutic agent of interest is a protein, it may be coupled to the surface of the erythrocyte by linkingbiotin to the protein and to another molecule on the erythrocyte surface, and then addingstreptavidin to bridge the two.[7] Similarly, therapeuticnanoparticles may attach to or embed in the red cell membranes orglycocalyx based on the chemical and physical properties of their surface ligands.[1]
For some therapeutic proteins it is only feasible to encapsulate the protein within the red cell membrane. In these cases the red blood cells must be partially lysed under isotonic conditions in the presence of the protein to be loaded, forming re-sealed erythrocytes orerythrocyte ghosts containing the protein of interest.[4][8]
In other applications, therapeutic nanoparticles larger than proteins but smaller than erythrocytes may be "cloaked" in red blood cell membranes in order to evade immune reaction or prolong circulation.[9] This may be accomplished by hypotonic lysis or extrusion of intact red cells, followed by re-extrusion in the presence of the nanoparticles.[10] This approach may also be used to encapsulate small molecules invesicles made from the plasma membrane of erythrocytes, if delivery particles smaller than intact cells are desired.[3]
The original application of erythrocytes for drug delivery was in enzyme replacement therapy,[4] and several variants of this concept have been developed. For example,glutamine synthetase,adenosine deaminase, andβ-galactosidase have been successfully encapsulated within erythrocytes to treat metabolic conditions.[5]
EBDDSs have been studied as delivery systems for chemotherapy agents. For instance, erythrocyte-encapsulated L-asparaginase has been studied as a therapy for acute lymphoblastic leukemia (ALL) and pancreatic ductal adenocarcinoma (PDAC).[11] Animal studies of erythrocyte-encapsulateddoxorubicin showed promise against lymphoid cancers and reduced cardiotoxicity relative to nonencapsulated doxorubicin.[5][11]
Steroid agents such ascorticosteroids, which often suffer poorbioavailability,[12] can be successfully delivered using EBDDS. Erythrocyte delivery of the corticosteroid derivative dexamethasone 21-phosphate has been approved by theEuropean Medical Agency as an orphan technology for treatment ofulcerative colitis. This system is also being investigated for conditions includingCrohn's disease,chronic obstructive pulmonary disease, andcystic fibrosis.[1]