Human genetic enhancement


Human genetic enhancement, human genetic modification or human genetic engineering refers to human enhancement by means of a genetic modification. This could be done in order to cure diseases, prevent the possibility of getting a particular disease, to improve athlete performance in sporting events, or to change physical appearance, metabolism, and even improve physical capabilities and mental faculties such as memory and intelligence.
These genetic enhancements may or may not be done in such a way that the change is heritable.

Ethics

Genetics is the study of genes and inherited traits and while the ongoing advancements in this field have resulted in the advancement of healthcare at multiple levels, ethical considerations have become increasingly crucial especially alongside. Genetic engineering has always been a topic of moral debate among bioethicists. Even though the technological advancements in this field present exciting prospects for biomedical improvement, it also prompts the need for ethical, societal, and practical assessments to understand its impact on human biology, evolution, and the environment. Genetic testing, genetic engineering, and stem cell research are often discussed together due to the interrelated moral arguments surrounding these topics. The distinction between repairing genes and enhancing genes is a central idea in many moral debates surrounding genetic enhancement because some argue that repairing genes is morally permissible, but that genetic enhancement is not due to its potential to lead to social injustice through discriminatory eugenics initiatives.
Moral questions related to genetic testing are often related to duty to warn family members if an inherited disorder is discovered, how physicians should navigate patient autonomy and confidentiality with regard to genetic testing, the ethics of genetic discrimination, and the moral permissibility of using genetic testing to avoid causing seriously disabled persons to exist, such as through selective abortion.
The responsibility of public health professionals is to determine potential exposures and suggest testing for communicable diseases that require reporting. Public health professionals may encounter disclosure concerns if the extension of obligatory screening results in genetic abnormalities being classified as reportable conditions.
Genetic data is personal and closely linked to a person's identity. Confidentiality concerns not only work, health care, and insurance coverage, but a family's whole genetic test results can be impacted. Affected individuals may also have their parents, children, siblings, sisters, and even extended relatives if the condition is either genetically dominant or carried by them. Moreover, a person's decisions could change their entire life depending on the outcome of a genetic test. Results of genetic testing may need to be disclosed in all facets of a person's life.
Non-invasive prenatal testing can accurately determine the sex of the fetus at an early stage of gestation, raising concerns about the potential facilitation of sex-selective termination of pregnancy due to its ease, timing, and precision. Even though the ultrasound technology can do the same, NIPT is being explored due to its capability to accurately identify the fetus's sex at an early stage in pregnancy, with increasing precision as early as 7 weeks' gestation. This timeframe precedes the typical timing for other sex determination techniques, such as ultrasound or chorionic villus sampling. The high early accuracy of NIPT reduces the uncertainty associated with other methods, such as the aforementioned, leading to more informed decisions and eliminating the risk of inaccurate results that could influence decision-making regarding sex-selective TOP. Additionally, NIPT enables sex-selective TOP in the first trimester, which is more practical, and allows pregnant women to postpone maternal-fetal bonding. These considerations may significantly facilitate the pursuit of sex-selective TOP when NIPT is utilized. Therefore, it is crucial to examine these ethical concerns within the framework of NIPT adoption.
Ethical issues related to gene therapy and human genetic enhancement concern the medical risks and benefits of the therapy, the duty to use the procedures to prevent suffering, reproductive freedom in genetic choices, and the morality of practicing positive genetics, which includes attempts to improve normal functions.
In every genetic based study conducted for humanity, studies must be carried out in accordance with the ethics committee approval statement, ethical, legal norms and human morality. CAR T cell therapy, which is intended to be a new treatment aims to change the genetics of T cells and transform immune system cells that do not recognize cancer into cells that recognize and fight cancer. it works with the T cell therapy method, which is arranged with palindromic repeats at certain short intervals called CRISPR.
All research involving human subjects in healthcare settings must be registered in a public database before the recruitment of the first trial. The informed consent statement should include adequate information about possible conflicts of interest, the expected benefits of the study, its potential risks, and other issues related to the discomfort it may involve.
Technological advancements play an integral role in new forms of human enhancement. While phenotypic and somatic interventions for human enhancement provide noteworthy ethical and sociological dilemmas, germline heritable genetic intervention necessitates even more comprehensive deliberations at the individual and societal levels.
Moral judgments are empirically based and entail evaluating prospective risk-benefit ratios particularly in the field of biomedicine. The technology of CRISPR genome editing raises ethical questions for several reasons. To be more specific, concerns exist regarding the capabilities and technological constraints of CRISPR technology. Furthermore, the long-term effects of the altered organisms and the possibility of the edited genes being passed down to succeeding generations and having unanticipated effects are two further issues to be concerned about. Decision-making on morality becomes more difficult when uncertainty from these circumstances prevents appropriate risk/benefit assessments.
The potential benefits of revolutionary tools like CRISPR are endless. For example, because it can be applied directly in the embryo, CRISPR/Cas9 reduces the time required to modify target genes compared to gene targeting technologies that rely on the use of embryonic stem cells. Bioinformatics tools developed to identify the optimal sequences for designing guide RNAs and optimization of experimental conditions have provided very robust procedures that guarantee the successful introduction of the desired mutation. Major benefits are likely to develop from the use of safe and effective HGGM, making a precautionary stance against HGGM unethical.
Going forward, many people support the establishment of an organization that would provide guidance on how best to control the ethical complexities mentioned above. Recently, a group of scientists founded the Association for Responsible Research and Innovation in Genome Editing to study and provide guidance on the ethical use of genome editing.
In addition, Jasanoff and Hurlbut have recently advocated for the establishment and international development of an interdisciplinary "global observatory for gene regulation".
Researchers proposed that debates in gene editing should not be controlled by the scientific community. The network is envisioned to focus on gathering information from dispersed sources, bringing to the fore perspectives that are often overlooked, and fostering exchange across disciplinary and cultural divides.
The interventions aimed at enhancing human traits from a genetic perspective are emphasized as being contingent upon the understanding of genetic engineering, and comprehending the outcomes of these interventions requires an understanding of the interactions between humans and other living beings. Therefore, the regulation of genetic engineering underscores the significance of examining the knowledge between humans and the environment.
To address the ethical challenges and uncertainties arising from genetic advancements, the development of comprehensive guidelines based on universal principles has been emphasized as essential. The importance of adopting a cautious approach to safeguard fundamental values such as autonomy, global well-being, and individual dignity has been elucidated when overcoming these challenges.
When contemplating genetic enhancement, genetic technologies should be approached from a broad perspective, using a definition that encompasses not only direct genetic manipulation but also indirect technologies such as biosynthetic drugs. It has been emphasized that attention should be given to expectations that can shape the marketing and availability of these technologies, anticipating the allure of new treatments. These expectations have been noted to potentially signify the encouragement of appropriate public policies and effective professional regulations.
Clinical stem cell research must be conducted in accordance with ethical values. This entails a full respect for ethical principles, including the accurate assessment of the balance between risks and benefits, as well as obtaining informed and voluntary participant consent. The design of research should be strengthened, scientific and ethical reviews should be effectively coordinated, assurance should be provided that participants understand the fundamental features of the research, and full compliance with additional ethical requirements for disclosing negative findings has been addressed.
Clinicians have been emphasized to understand the role of genomic medicine in accurately diagnosing patients and guiding treatment decisions. It has been highlighted that detailed clinical information and expert opinions are crucial for the accurate interpretation of genetic variants. While personalized medicine applications are exciting, it has been noted that the impact and evidence base of each intervention should be carefully evaluated. The human genome contains millions of genetic variants, so caution should be exercised and expert opinions sought when analyzing genomic results.