Methods and compositions to improve germ cell and embryo...

Drug – bio-affecting and body treating compositions – Designated organic active ingredient containing – Carbohydrate doai

Reexamination Certificate

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C435S002000, C424S009100

Reexamination Certificate

active

06593309

ABSTRACT:

TECHNICAL FIELD
The present invention relates generally to the use of polysaccharides containing arabinose, galactose and/or hexuronic acid in promoting in vivo and in vitro survival and improved function of sperm, oocytes, and embryos.
BACKGROUND OF THE INVENTION
In nature, fertilization occurs by sperm cells being deposited into the female of warm-blooded animal species (including humans) and then binding to and fusing with an oocyte. This fertilized oocyte then divides to form an embryo. Over the last several decades, the use of assisted reproduction techniques has allowed scientists and clinicians to intervene in these events to treat poor fertility in some individuals or to store sperm, oocytes or embryos for use at other locations or times. The procedures utilized in these cases include: washing a sperm sample to separate out the sperm-rich fraction from non-sperm components of a sample such as seminal plasma or debris; further isolating the healthy, motile (swimming) sperm from dead sperm or from white blood cells in an ejaculate; freezing or refrigerating of sperm (storage) for use at a later date or for shipping to females at differing locations; extending or diluting sperm for culture in diagnostic testing or for use in therapeutic interventions such as in vitro fertilization (IVF) or intracytoplasmic sperm injection (ICSI); culturing or freezing oocytes from the female for use in in vitro fertilization; and culturing or freezing of embryos prior to transfer back to a female in order to establish a pregnancy.
At each step of the way, in vitro intervention decreases the normal survival and function of sperm, oocytes, and embryos. Much research has been dedicated towards improving these procedures; however, overall success remains limited. For example, <20% of IVF attempts result in the birth of a child. Additionally, only half or less of sperm cells routinely survive the freezing process, such that pregnancy rates with frozen sperm from donors average between 10 and 20%. Oocytes and embryos also show significantly disrupted function after culture or freezing. Specifically, human oocytes survive the freezing process at very low levels. Thus, in spite of several decades of work, much room remains for improvement in the field of assisted reproduction technologies and especially in gamete and embryo handling, culture, and storage.
One common procedure used in sperm collection is washing sperm cells. Washing sperm prior to its use in assisted reproduction technologies is important for a variety of reasons. An ejaculate contains seminal plasma in addition to sperm cells, and the sugars and proteins in seminal plasma can be toxic to sperm cells after ejaculation. Also, sperm samples that have been frozen contain cryopreservation media which needs to be washed from the sperm cells prior to insemination in the female of some species, particularly birds and women. For all species, cryopreservative media cause lipid membrane peroxidation (LPO) and degeneration of the sperm after thawing. Generally, washing involves centrifuging a sample of semen or thawed sperm through a diluting wash media, which allows collection of a sperm-rich pellet. Although a very common procedure, centrifugation itself can cause sperm lipid peroxidation and membrane breakdown.
After a sperm wash process, or in place of it, a specific procedure for the isolation of the motile sperm from a sample may be done. An ejaculate contains dead and dying sperm that release enzymes that can damage the live, motile sperm. In addition, an ejaculate contains white blood cells, red blood cells, and bacteria which are also toxic to the healthy sperm in an ejaculate. Sperm isolations involve separating out the live, healthy, and motile sperm for use in diagnostic or therapeutic procedures. Generally, sperm are isolated by allowing the motile sperm to swim away from the dead sperm and debris (sperm swim-up), by centrifuging the sperm through a density gradient, or by passing the sperm through a column that binds the dead sperm and debris. Each of these techniques has its own disadvantages. Swim-up only recovers low sperm numbers, and it requires a long culture period. Current centrifugation gradient reagents are generally toxic to sperm, such that an added wash step is necessary to remove the gradient solution from the sperm sample. Column methods have poor selectivity for motile sperm and do not always result in good recovery of sperm numbers from a full ejaculate.
Once sperm have been washed or isolated, they are then extended (or diluted) in culture or holding media for a variety of uses. Existing sperm culture techniques result in losses of motile sperm and also damage sperm DNA over time in culture. Although sperm survive for days in the females of most species, sperm survival in culture is typically only half as long as that seen in vivo, and sperm from males with poor quality ejaculates may survive for even shorter time periods in culture. Much of this damage is due to lipid peroxidation of the membrane and DNA or chromatin breakdown. Sperm are extended in media for use in sperm analysis and diagnostic tests; assisted reproduction technologies, such as IVF, gamete intrafallopian transfer, or ICSI; insemination into the female; and holding prior to cryopreservation. Each of these uses for extended or diluted sperm requires a somewhat different formulation of basal medium; however, in all cases sperm survival is suboptimal outside of the female reproductive tract.
Likewise, oocytes and embryos often develop abnormally (e.g., chromosome number, cytoskeleton formation) in culture compared to in vivo conditions. Additionally, current culture methods utilize high doses of animal proteins, like serum, which may result in an oversized fetus and perinatal complication for the offspring.
Some of the difficulties in assisted reproduction technologies can be overcome by coculturing sperm, oocytes and embryos with cell feeder layers. However, cocultures are of variable quality and variable reliability and add the risk of pathogen transfer from the feeder cells to the gametes or embryos that are to be transferred back to living animals or humans.
Storage of sperm is of widespread importance in commercial animal breeding programs, human sperm donor programs and in dealing with some disease states. For example, sperm samples may be frozen for men who have been diagnosed with cancer or other diseases that may eventually interfere with sperm production. Freezing and storage of sperm is critical in the area of preservation of endangered species. Many of these species have semen which does not freeze well under existing methods. In standard animal husbandry, artificial insemination (AI) with frozen bull sperm is used in 85% of dairy cows. Because most commercial turkeys have become too heavy to mate naturally, AI is required on almost all turkey farms. Approximately six million turkey hens are inseminated each week in the United States. However, existing methods of storing collected turkey sperm cannot support sperm survival for even the several hours required to transport semen between farms, much less for long-term freezing. This limits the ability to store or transport genetic material to improve production. Human donor AI is also used for couples with severe male infertility; however, pregnancy rates with donor semen in people is only a quarter of that found with natural reproduction. Furthermore, surgical insemination may be required.
Current techniques for freezing sperm from all species result in membrane damage and subsequent death of about half of the sperm cells in a sample. Much of this damage occurs by reactive oxygen species causing lipid peroxidation of the sperm membrane. Despite these widespread and serious problems, the state of the art and protocols for this field have changed very little in the last 15 years. In light of the increasing use of frozen sperm in a variety of settings, a new method of freezing or storing sperm would offer a major breakthrough for human fertility specialists, animal producers, and cons

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