Utility of magnetic cell separation as a molecular sperm preparation technique

Abstract

Assisted reproductive techniques (ARTs) have become the treatment of choice in many cases of infertility; however, the current success rates of these procedures remain suboptimal. Programmed cell death (apoptosis) most likely contributes to failed ART and to the decrease in sperm quality after cryopreservation. There is a likelihood that some sperm selected for ART will display features of apoptosis despite their normal appearance, which may be partially responsible for the low fertilization and implantation rates seen with ART. One of the features of apoptosis is the externalization of phosphatidylserine (PS) residues, which are normally present on the inner leaflet of the sperm plasma membrane. Colloidal superparamagnetic microbeads ( approximately 50 nm in diameter) conjugated with annexin V bind to PS and are used to separate dead and apoptotic spermatozoa by magnetic-activated cell sorting (MACS). Cells with externalized PS will bind to these microbeads, whereas nonapoptotic cells with intact membranes do not bind and could be used during ARTs. We have conducted a series of experiments to investigate whether the MACS technology could be used to improve ART outcomes. Our results clearly indicate that integrating MACS as a part of sperm preparation techniques will improve semen quality and cryosurvival rates by eliminating apoptotic sperm. Nonapoptotic spermatozoa prepared by MACS display higher quality in terms of routine sperm parameters and apoptosis markers. The higher sperm quality is represented by an increased oocyte penetration potential and cryosurvival rates. Thus, the selection of nonapoptotic spermatozoa by MACS should be considered to enhance ART success rates.

Figure 1

Schematic diagram of MiniMACS magnetic cell separation column. A) The solid support consists of closely packed, sub-millimeter spheres made of soft steel alloy. An external magnetic field magnetizes the solid support, which attracts magnetically labeled cells from a mixture applied to the column. B) A thin slice across the solid support shows interstitial spaces available for flow of the cell mixture. C) The un-labeled cells flow freely through the column, while the magnetically labeled cells are retained inside the column and could be recovered by removal of the column from the magnetic field, followed by elution. Reprinted with permission of the Cleveland Clinic, 2007.