Having a laser system can help address a variety of cases in ART while optimising the workflow. It is, therefore, common today for embryology laboratories to have a laser system attached to the microscope at the ICSI workplace.
You are probably already familiar with the use of lasers for assisted hatching or embryo biopsy, since these are the most widely spread applications. There are, however, other ways in which you and your patients can benefit from the use of a laser system in the lab.
This was the first application and main reason why laser systems were originally developed for IVF. It consists of opening the zona pellucida in order to help the embryo during its hatching process. There are basically 2 different approaches for laser assisted hatching, commonly referred to as “zona drilling” and “zona thinning”.
Assisted hatching is used frequently in cases of implantation failure, advanced maternal age, poor endometrial receptivity, hardening of the zona (e.g. cryopreserved embryos).
Whenever preimplantation genetic testing of the embryo is indicated, a few cells must be removed from the embryo for subsequent analysis. This has been done by extracting a blastomere at day 3 or by extracting the polar body. Nowadays, this is preferably done by trophectoderm biopsy, a technique in which trophectoderm cells will be removed and analysed, so that the inner cell mass, and thus future fetus, can be left intact.
Common indications for embryo biopsy are increased maternal age, repetitive implantation failure, recurrent pregnancy loss, hereditary disease, idiopathic infertility.
Learn how to perform trophectoderm biopsy with Octax lasers in this technote.
Here you can see how I perform an embryo biopsy using the flicking technique:
And here is an example of how to perform embryo biopsy using the pulling technique:
The laser is also commonly used for collapsing the embryo prior to vitrification, as it has been found to yield better survival rates after warming. This is done by applying a laser pulse on a well expanded blastocyst between 2 trophectoderm cells towards the zona pellucida. Once the embryo has collapsed, it can be vitrified. This collapsing procedure allows the cryoprotectants to better penetrate the blastocyst and, therefore, leads to a more effective vitrification/warming.
Learn how to perform blastocyst collapsing with Octax lasers in this technote.
This is often a less known laser application, yet quite useful, especially if you are dealing with cases of severe male factor such as severe asthenozoospermia or when doing ICSI with sperm extracted from the testis as these have not yet acquired their motility ability. Whenever you need to choose between immotile sperm prior to injection, using the laser will help you to identify if a sperm is viable or not. Simply apply a single laser pulse on the tip of the flagellum and wait to see whether there is a membrane reaction. If the sperm reacts, which is evident by a curling of the tail, it means that it is viable. And if there is no reaction, it is not and should not be used.
Learn how to perform sperm viability testing with Octax lasers in this technote.
There are other approaches to the above-mentioned procedures. For example, an embryo biopsy can be done mechanically, chemically. These, however, may be too cumbersome, invasive or inconsistent approaches. Using a laser has become a reliable way to work in a safe and consistent manner, thus optimising your workflow and the results for your patients.
In general, there are 2 types of laser systems, static lasers and dynamic lasers. This has a historical reason as originally the lasers were static, meaning that the laser has a fixed position and thus the embryo must be moved to the target, which is not a big deal when one pulse is needed. However, whenever multiple pulses are required, it can be quite time-consuming and impractical to have a fixed laser. Eventually, it became necessary to have more flexibility and dynamic lasers were developed giving embryologists improved control and workflow.
Octax laser systems are considered the pioneers for use in IVF, being the first available since the 90s and with a solid foundation of extensive research leading up to the development. Therefore, we count on a highly robust reliable system of proven safety.
Our static version is known as LaserShot, it is a robust calibration-free system with superior image quality. It can be upgraded to a dynamic one.
Our dynamic version is known as NaviLase, it is our most advanced option available and a popular one today among users because given its dynamic features, flexibility and ease of use, additional to all the same advantages of a LaserShot.
When you work with NaviLase, you have different working modes depending on your specific application.
Working modes:
Octax lasers have a long history in IVF. Pioneering and extensive research in the mid-1990s resulted in the 1.48 μm Octax laser becoming the worldwide standard for all lasers used in IVF. A multitude of pre-clinical and clinical studies have proven the safety of Octax lasers. With tens of thousands of children born after laser treatment and with no adverse effects, you can be sure your gametes and embryos are safe during laser procedures performed using Octax lasers. Find a list of publications using Octax lasers here.
Download a short visual guide of Octax laser and imaging systems below.
Please note that Octax lasers are not available in all markets due to local limitations. Not available in the US. Intended use may vary in different markets.