High performance collection of cerebrospinal fluid in rats: evaluation of erythropoietin penetration after osmotic opening of the blood-brain barrier.

An important issue to be considered when studying a new drug for treatment of central nervous system (CNS) diseases is its ability to cross the blood-brain barrier (BBB) and distribute throughout the brain. As cerebrospinal fluid (CSF) has demonstrated to be an invaluable reservoir to study CNS availability of therapeutic proteins, we have developed an improved method for CSF sampling from the cisterna magna of rats. The technique enables the simple and rapid collection of adequate quantities (50-75 µl) of blood-free CSF, rendering a high percentage of animal survival (99%) without clinic or neurological consequences. Its success in avoiding blood contamination of CSF lays in the use of a mixture of lidocaine/ephinephrine topically injected in the rat's suboccipital area and neck. Another relevant feature of the methodology is its low cost, since the puncture device can be easily assembled with cheap and available materials and, more importantly, neither expensive stereotaxic equipment nor frame is required. The present method is demonstrated by studying the CSF pharmacokinetics of recombinant human erythropoietin (rhEPO), a well-studied therapeutic candidate for neurological diseases. Moreover, we applied this technique to evaluate a strategy of osmotic disruption of the BBB to achieve a faster delivery of rhEPO into the CNS.

A versatile ionic strength sensitive tag from a human GM-CSF-derived linear epitope.

A 7-mer hGM-CSF-derived linear epitope (APARSPS) is herein described as a novel and small tag taking into account its particular binding affinity in native conditions that could be easily modified by increasing or lowering the ionic strength. Thus, a 3.4 or 3.8-fold binding increment was observed in high NaCl concentration when the tag was fused to IFN-α2b or when the peptide was in its native environment, respectively. The high salt concentration increased the affinity of the binding interaction and improved the APARSPS epitope binding to the paratope allowing one to design an immunoaffinity chromatography purification step in which the high ionic strength was useful to adsorb the fusion protein to the immunoaffinity matrix and the low ionic strength at pH 9 was valuable to desorb it (a 470-fold purification with a 94%-purity was attained in only one step). Also, this short tag did not affect the functionality of the fusion protein and it was able to be detected both in the natural molecule (hGM-CSF) as in the tagged one with the same high detection limit: 273pg of each protein.

Isolation and characterization of a subset of erythropoietin glycoforms with cytoprotective but minimal erythropoietic activity.

Although historically used for the treatment of anemia, erythropoietin (EPO) has emerged as a neurotrophic and neuroprotective agent in different conditions of neuronal damage (traumatic brain injury, ischemia, spinal cord compression, peripheral neuropathy, retinal damage, epilepsy, Parkinson's Disease, among others). Nonetheless, EPO's therapeutic application is limited due to its hematological side-effects. With the aim of obtaining EPO derivatives resembling the hormone isolated from cells and tissues of neural origin, a novel combination of less acidic EPO glycoforms -designated as neuroepoetin (rhNEPO)- was purified to homogeneity from the supernatant of a CHO-producing cell line by a four-step chromatographic procedure. This simple and single process allowed us to prepare two EPO derivatives with distinct therapeutic expectations: the hematopoietic version and a minimally hematopoietic, but mainly in vitro cytoprotective, alternative. Further biological characterization showed that the in vivo erythropoietic activity of rhNEPO was 25-times lower than that of rhEPO. Interestingly, using different in vitro cytoprotective assays we found that this molecule exerts cytoprotection equivalent to, or better than, that of rhEPO in cells of neural phenotype. Furthermore, despite its shorter plasma half-life, rhNEPO was rapidly absorbed and promptly detected in the cerebrospinal fluid after intravenous administration in rats (5 min postinjection, in comparison with 30 min for rhEPO). Therefore, our results support the study of neuroepoetin as a potential drug for the treatment of neurological diseases, combining high cytoprotective activity with reduced hematological side-effects.