Designer baby
It has been suggested that this article be merged into Human germline engineering. (Discuss) Proposed since December 2018. |
A designer baby is a baby whose genetic makeup has been selected or altered, often to include a particular gene or to remove genes associated with a disease.[1] This process usually involves analysing a wide range of human embryos to identify genes associated with particular diseases and characteristics, and selecting embryos that have the desired genetic makeup; a process known as preimplantation genetic diagnosis. Other potential methods by which a baby's genetic information can be altered involve directly editing the genome – a person's genetic code – before birth. This process is not routinely performed and only one instance of this is known to have occurred as of 2019, where Chinese twins Lulu and Nana were edited as embryos, causing widespread criticism.[2]
Genetically altered embryos can be achieved by introducing the desired genetic material into the embryo itself, or into the sperm and/or egg cells of the parents; either by delivering the desired genes directly into the cell or using the gene-editing technology. This process is known as germline engineering and performing this on embryos that will be brought to term is not typically permitted by law.[3] Editing embryos in this manner means that the genetic changes can be carried down to future generations, and since the technology concerns editing the genes of an unborn baby, it is considered controversial and is subject to ethical debate.[4] While some scientists condone the use of this technology to treat disease, some have raised concerns that this could be translated into using the technology for cosmetic means and enhancement of human traits, with implications for the wider society.[5]
Pre-implantation genetic diagnosis
Pre-implantation genetic diagnosis (PGD or PIGD) is a procedure in which embryos are screened prior to implantation. The technique is used alongside in vitro fertilisation (IVF) to obtain embryos for evaluation of the genome – alternatively, ovocytes can be screened prior to fertilisation. The technique was first used in 1989.[6]
PGD is used primarily to select embryos for implantation in the case of possible genetic defects, allowing identification of mutated or disease-related alleles and selection against them. It is especially useful in embryos from parents where one or both carry a heritable disease. PGD can also be used to select for embryos of a certain sex, most commonly when a disease is more strongly associated with one sex than the other (as is the case for X-linked disorders which are more common in males, such as haemophilia). Infants born with traits selected following PGD are sometimes considered to be designer babies.[7]
One application of PGD is the selection of ‘saviour siblings’, children who are born to provide a transplant (of an organ or group of cells) to a sibling with a usually life-threatening disease. Saviour siblings are conceived through IVF and then screened using PGD to analyse genetic similarity to the child needing a transplant, in order to reduce the risk of rejection.[8]
Process
Embryos for PGD are obtained from IVF procedures in which the oocyte is artificially fertilised by sperm. Oocytes from the woman are harvested following controlled ovarian hyperstimulation (COH), which involves fertility treatments to induce production of multiple oocytes. After harvesting the oocytes, they are fertilised in vitro, either during incubation with multiple sperm cells in culture, or via intracytoplasmic sperm injection (ICSI), where sperm is directly injected into the oocyte. The resulting embryos are usually cultured for 3–6 days, allowing them to reach the blastomere or blastocyst stage.[9]
Once embryos reach the desired stage of development, cells are biopsied and genetically screened. The screening procedure varies based on the nature of the disorder being investigated.
Polymerase chain reaction (PCR) is a process in which DNA sequences are amplified to produce many more copies of the same segment, allowing screening of large samples and identification of specific genes.[10] The process is often used when screening for monogenic disorders, such as cystic fibrosis.
Another screening technique, fluorescent in situ hybridisation (FISH) uses fluorescent probes which specifically bind to highly complementary sequences on chromosomes, which can then be identified using fluorescence microscopy.[11] FISH is often used when screening for chromosomal abnormalities such as aneuploidy, making it a useful tool when screening for disorders such as Down syndrome.
Following screening, embryos with the desired trait (or lacking an undesired trait such as a mutation) are transferred into the mother's uterus, then allowed to develop naturally.
Regulation
PGD regulation is determined by individual countries’ governments, with some prohibiting its use entirely, including in Austria, China, and Ireland.[12]
In many countries, PGD is permitted under very stringent conditions for medical use only, as is the case in France, Switzerland, Italy and the United Kingdom.[13][14] Whilst PGD in Italy and Switzerland is only permitted under certain circumstances, there is no clear set of specifications under which PGD can be carried out, and selection of embryos based on sex is not permitted. In France and the UK, regulations are much more detailed, with dedicated agencies setting out framework for PGD.[15][16] Selection based on sex is permitted under certain circumstances, and genetic disorders for which PGD is permitted are detailed by the countries’ respective agencies.
In contrast, the United States federal law does not regulate PGD, with no dedicated agencies specifying regulatory framework by which healthcare professionals must abide.[13] Elective sex selection is permitted, accounting for around 9% of all PGD cases in the U.S., as is selection for desired conditions such as deafness or dwarfism.[17]
Human germline engineering
Human germline engineering is a process in which the human genome is edited within a germ cell, such as a sperm cell or oocyte (causing heritable changes), or in the zygote or embryo following fertilisation.[18] Germline engineering results in changes in the genome being incorporated into every cell in the body of the offspring (or of the individual following embryonic germline engineering). This process differs from somatic cell engineering, which does not result in heritable changes. Most human germline editing is performed on individual cells and non-viable embryos, which are destroyed at a very early stage of development. In November 2018, however, a Chinese scientist, He Jiankui, announced that he had created the first human germline genetically edited babies.[19]
Genetic engineering relies on a knowledge of human genetic information, made possible by research such as the Human Genome Project, which identified the position and function of all the genes in the human genome.[20] As of 2019, high-throughput sequencing methods allow genome sequencing to be conducted very rapidly, making the technology widely available to researchers.[21]
Germline modification is typically accomplished through techniques which incorporate a new gene into the genome of the embryo or germ cell in a specific location. This can be achieved by introducing the desired DNA directly to the cell for it to be incorporated, or by replacing a gene with one of interest. These techniques can also be used to remove or disrupt unwanted genes, such as ones containing mutated sequences.
Whilst germline engineering has mostly been performed in mammals and other animals, research on human cells in vitro is becoming more common. Most commonly used in human cells are germline gene therapy and the engineered nuclease system CRISPR/Cas9.
Germline gene therapy
Gene therapy is the delivery of a nucleic acid (usually DNA or RNA) into a cell as a pharmaceutical agent to treat disease.[22] Most commonly it is carried out using a vector, which transports the nucleic acid (usually DNA encoding a therapeutic gene) into the target cell. A vector can transduce a desired copy of a gene into a specific location to be expressed as required. Alternatively, a transgene can be inserted to deliberately disrupt an unwanted or mutated gene, preventing transcription and translation of the faulty gene products to avoid a disease phenotype.
Gene therapy in patients is typically carried out on somatic cells in order to treat conditions such as some leukaemias and vascular diseases.[23][24][25] Human germline gene therapy in contrast is restricted to in vitro experiments in some countries, whilst others prohibited it entirely, including Australia, Canada, Germany and Switzerland.[26]
Whilst the National Institutes of Health in the US does not currently allow in utero germline gene transfer clinical trials, in vitro trials are permitted.[27] The NIH guidelines state that further studies are required regarding the safety of gene transfer protocols before in utero research is considered, requiring current studies to provide demonstrable efficacy of the techniques in the laboratory.[28] Research of this sort is currently using non-viable embryos to investigate the efficacy of germline gene therapy in treatment of disorders such as inherited mitochondrial diseases.[29]
Gene transfer to cells is usually by vector delivery. Vectors are typically divided into two classes – viral and non-viral.
Viral vectors
Viruses infect cells by transducing their genetic material into a host's cell, using the host's cellular machinery to generate viral proteins needed for replication and proliferation. By modifying viruses and loading them with the therapeutic DNA or RNA of interest, it is possible to use these as a vector to provide delivery of the desired gene into the cell.[30]
Retroviruses are some of the most commonly used viral vectors, as they not only introduce their genetic material into the host cell, but also copy it into the host's genome. In the context of gene therapy, this allows permanent integration of the gene of interest into the patient's own DNA, providing longer lasting effects.[31]
Viral vectors work efficiently and are mostly safe but present with some complications, contributing to the stringency of regulation on gene therapy. Despite partial inactivation of viral vectors in gene therapy research, they can still be immunogenic and elicit an immune response. This can impede viral delivery of the gene of interest, as well as cause complications for the patient themselves when used clinically, especially in those already suffering from a serious genetic illness.[32] Another difficulty is the possibility that some viruses will randomly integrate their nucleic acids into the genome, which can interrupt gene function and generate new mutations.[33] This is a significant concern when considering germline gene therapy, due to the potential to generate new mutations in the embryo or offspring.
Non-viral vectors
Non-viral methods of nucleic acid transfection involved injecting a naked DNA plasmid into cell for incorporation into the genome.[34] This method used to be relatively ineffective with low frequency of integration, however, efficiency has since greatly improved, using methods to enhance the delivery of the gene of interest into cells. Furthermore, non-viral vectors are simple to produce on a large scale and are not highly immunogenic.
Some non-viral methods are detailed below:
- Electroporation is a technique in which high voltage pulses are used to carry DNA into the target cell across the membrane. The method is believed to function due to the formation of pores across the membrane, but although these are temporary, electroporation results in a high rate of cell death which has limited its use.[35] An improved version of this technology, electron-avalanche transfection, has since been developed, which involves shorter (microsecond) high voltage pulses which result in more effective DNA integration and less cellular damage.[36]
- The gene gun is a physical method of DNA transfection, where a DNA plasmid is loaded onto a particle of heavy metal (usually gold) and loaded onto the ‘gun’.[37] The device generates a force to penetrate the cell membrane, allowing the DNA to enter whilst retaining the metal particle.
- Oligonucleotides are used as chemical vectors for gene therapy, often used to disrupt mutated DNA sequences to prevent their expression.[38] Disruption in this way can be achieved by introduction of small RNA molecules, called siRNA, which signal cellular machinery to cleave the unwanted mRNA sequences to prevent their transcription. Another method utilises double-stranded oligonucleotides, which bind transcription factors required for transcription of the target gene. By competitively binding these transcription factors, the oligonucleotides can prevent the gene's expression.
ZFNs
Zinc-finger nucleases (ZFNs) are enzymes generated by fusing a zinc finger DNA-binding domain to a DNA-cleavage domain. Zinc finger recognizes between 9 and 18 bases of sequence. Thus by mixing those modules, it becomes easier to target any sequence researchers wish to alter ideally within complex genomes. A ZFN is a macromolecular complex formed by monomers in which each subunit contains a zinc domain and a FokI endonuclease domain. The FokI domains must dimerize for activities, thus narrowing target area by ensuring that two close DNA-binding events occurs.[39]
The resulting cleavage event enables most genome-editing technologies to work. After a break is created, the cell seeks to repair it.
- A method is NHEJ, in which the cell polishes the two ends of broken DNA and seals them back together, often producing a frame shift.
- An alternative method is homology-directed repairs. The cell tries to fix the damage by using a copy of the sequence as a backup. By supplying their own template, researcher can have the system to insert a desired sequence instead.[39]
The success of using ZFNs in gene therapy depends on the insertion of genes to the chromosomal target area without causing damage to the cell. Custom ZFNs offer an option in human cells for gene correction.
TALENs
There is a method called TALENs that targets singular nucleotides. TALENs stand for transcription activator-like effector nucleases. TALENs are made by TAL effector DNA-binding domain to a DNA cleavage domain. All these methods work by as the TALENs are arranged. TALENs are “built from arrays of 33-35 amino acid modules…by assembling those arrays…researchers can target any sequence they like”.[39] This event is referred as Repeat Variable Diresidue (RVD). The relationship between the amino acids enables researchers to engineer a specific DNA domain. The TALEN enzymes are designed to remove specific parts of the DNA strands and replace the section; which enables edits to be made. TALENs can be used to edit genomes using non-homologous end joining (NHEJ) and homology directed repair.
CRISPR/Cas9
The CRISPR/Cas9 system (CRISPR – Clustered Regularly Interspaced Short Palindromic Repeats, Cas9 – CRISPR-associated protein 9) is a genome editing technology based on the bacterial antiviral CRISPR/Cas system. The bacterial system has evolved to recognise viral nucleic acid sequences and cut these sequences upon recognition, damaging infecting viruses. The gene editing technology uses a simplified version of this process, manipulating the components of the bacterial system to allow location-specific gene editing.[40]
The CRISPR/Cas9 system broadly consists of two major components – the Cas9 nuclease and a guide RNA (gRNA). The gRNA contains a Cas-binding sequence and a ~20 nucleotide spacer sequence, which is specific and complementary to the target sequence on the DNA of interest. Editing specificity can therefore be changed by modifying this spacer sequence.[40]
Upon system delivery to a cell, Cas9 and the gRNA bind, forming a ribonucleoprotein complex. This causes a conformational change in Cas9, allowing it to cleave DNA if the gRNA spacer sequence binds with sufficient homology to a particular sequence in the host genome.[41] When the gRNA binds to the target sequence, Cas will cleave the locus, causing a double-strand break (DSB).
The resulting DSB can be repaired by one of two mechanisms –
- Non-Homologous End Joining (NHEJ) - an efficient but error-prone mechanism, which often introduces insertions and deletions (indels) at the DSB site. This means it is often used in knockout experiments to disrupt genes and introduce loss of function mutations.
- Homology Directed Repair (HDR) - a less efficient but high-fidelity process which is used to introduce precise modifications into the target sequence. The process requires adding a DNA repair template including a desired sequence, which the cell's machinery uses to repair the DSB, incorporating the sequence of interest into the genome.
Since NHEJ is more efficient than HDR, most DSBs will be repaired via NHEJ, introducing gene knockouts. To increase frequency of HDR, inhibiting genes associated with NHEJ and performing the process in particular cell cycle phases (primarily S and G2) appear effective.
CRISPR/Cas9 is an effective way of manipulating the genome in vivo in animals as well as in human cells in vitro, but some issues with the efficiency of delivery and editing mean that it is not considered safe for use in viable human embryos or in the body's germ cells. As well as the higher efficiency of NHEJ making inadvertent knockouts likely, CRISPR can introduce DSBs to unintended parts of the genome, called off-target effects.[42] These arise due to the spacer sequence of the gRNA conferring sufficient sequence homology to random loci in the genome, which can introduce random mutations throughout. If performed in germline cells, mutations could be introduced to all the cells of a developing embryo.
Regulation on CRISPR use
In 2015, the International Summit on Human Gene Editing was held in Washington D.C., hosted by scientists from China, the UK and the U.S.. The summit concluded that genome editing of somatic cells using CRISPR and other genome editing tools would be allowed to proceed under FDA regulations, but human germline engineering would not be pursued.[27]
In February 2016, scientists at the Francis Crick Institute in London were given a license permitting them to edit human embryos using CRISPR to investigate early development.[43] Regulations were imposed to prevent the researchers from implanting the embryos and to ensure experiments were stopped and embryos destroyed after seven days.
In November 2018, Chinese scientist He Jiankui announced that he had performed the first germline engineering on viable humans embryos, which have since been brought to term.[19] The research claims received significant criticism, and Chinese authorities suspended He's research activity.[44] Following the event, scientists and government bodies have called for more stringent regulations to be imposed on the use of CRISPR technology in embryos, with some calling for a global moratorium on germline genetic engineering. Chinese authorities have announced stricter controls will be imposed, with Communist Party general secretary Xi Jinping and government premier Li Keqiang calling for new gene-editing legislations to be introduced.[45][46]
Lulu and Nana controversy
The Lulu and Nana controversy refers to the two Chinese twin girls born in November 2018, who had been genetically modified as embryos by the Chinese scientist He Jiankui.[19] The twins are believed to be the first genetically modified babies. The girls’ parents had participated in a clinical project run by He, which involved IVF, PGD and genome editing procedures in an attempt to edit the gene CCR5. CCR5 encodes a protein used by HIV to enter host cells, so by introducing a specific mutation into the gene CCR5 Δ32 He claimed that the process would confer innate resistance to HIV.[47][48]
The project run by He recruited couples wanting children where the man was HIV-positive and the woman uninfected. During the project, He performed IVF with sperm and eggs from the couples and then introduced the CCR5 Δ32 mutation into the genomes of the embryos using CRISPR/Cas9. He then used PGD on the edited embryos during which he sequenced biopsied cells to identify whether the mutation had been successfully introduced. He reported some mosaicism in the embryos, whereby the mutation had integrated into some cells but not all, suggesting the offspring would not be entirely protected against HIV.[49] He claimed that during the PGD and throughout the pregnancy, foetal DNA was sequenced to check for off-target errors introduced by the CRISPR/Cas9 technology, however the NIH released a statement in which they announced "the possibility of damaging off-target effects has not been satisfactorily explored".[50][51] The girls were born in early November 2018, and were reported by He to be healthy.[49]
He's research was conducted in secret until November 2018, when documents were posted on the Chinese clinical trials registry and MIT Technology Review published a story about the project.[52] Following this, He was interviewed by the Associated Press and presented his work on 27 November and the Second International Human Genome Editing Summit which was held in Hong Kong.[47]
The experiment was met with widespread criticism and was very controversial, globally as well as in China.[53][54] Several bioethicists, researchers and medical professionals have released statements condemning the research, including Nobel laureate David Baltimore who deemed the work “irresponsible” and one pioneer of the CRISPR/Cas9 technology, biochemist Jennifer Doudna at University of California, Berkeley.[50][55] The director of the NIH, Francis S. Collins stated that the “medical necessity for inactivation of CCR5 in these infants is utterly unconvincing” and condemned He Jiankui and his research team for ‘irresponsible work’.[51] Other scientists, including geneticist George Church of Harvard University suggested gene editing for disease resistance was “justifiable” but expressed reservations regarding the conduct of He's work.[56]
The World Health Organization has launched a global registry to track research on human genome editing, after a call to halt all work on genome editing.[57][58][59]
The Chinese Academy of Medical Sciences responded to the controversy in the journal Lancet, condemning He for violating ethical guidelines documented by the government and emphasising that germline engineering should not be performed for reproductive purposes.[60] The academy ensured they would “issue further operational, technical and ethical guidelines as soon as possible” to impose tighter regulation on human embryo editing.
Ethical considerations
Editing embryos, germ cells and the generation of designer babies is the subject of ethical debate, as a result of the implications in modifying genomic information in a heritable manner. Despite regulations set by individual countries’ governing bodies, the absence of a standardised regulatory framework leads to frequent discourse in discussion of germline engineering among scientists, ethicists and the general public. Arthur Caplan, the head of the Division of Bioethics at New York University suggests that establishing an international group to set guidelines for the topic would greatly benefit global discussion and proposes instating “religious and ethics and legal leaders” to impose well-informed regulations.[61]
In many countries, editing embryos and germline modification for reproductive use is illegal.[62] As of 2017, the U.S. restricts the use of germline modification and the procedure is under heavy regulation by the FDA and NIH.[62] The American National Academy of Sciences and National Academy of Medicine indicated they would provide qualified support for human germline editing "for serious conditions under stringent oversight", should safety and efficiency issues be addressed.[63]
Since genetic modification poses risk to any organism, researchers and medical professionals must give the prospect of germline engineering careful consideration. The main ethical concern is that these types of treatments will produce a change that can be passed down to future generations and therefore any error, known or unknown, will also be passed down and will affect the offspring.[64] Some bioethicists, including Ronald Green of Dartmouth College, raise concern that this could result in the accidental introduction of new diseases in future.[65][66]
When considering support for research into germline engineering, ethicists have often suggested that it can be considered unethical not to consider a technology which could improve the lives of children who would be born with congenital disorders. Geneticist George Church claims that he does not expect germline engineering to increase societal disadvantage, and recommends lowering costs and improving education surrounding the topic to dispel these views.[5] He emphasises that allowing germline engineering in children who would otherwise be born with congenital defects could save around 5% of babies from living with potentially avoidable diseases. Jackie Leach Scully, professor of social and bioethics at Newcastle University, acknowledges that the prospect of designer babies could leave those living with diseases and unable to afford the technology feeling marginalised and without medical support.[5] However, Professor Leach Scully also suggests that germline editing provides the option for parents “to try and secure what they think is the best start in life” and does not believe it should be ruled out. Similarly, Nick Bostrom, an Oxford philosopher known for his work on the risks of artificial intelligence, proposed that “super-enhanced” individuals could “change the world through their creativity and discoveries, and through innovations that everyone else would use”, highlighting not only a personal but societal benefit.[67]
Many bioethicists emphasise that germline engineering is usually considered in the best interest of a child, therefore associated should be supported. Dr James Hughes, a bioethicist at Trinity College, Connecticut, suggests that the decision may not differ greatly from others made by parents which are well accepted – choosing with whom to have a child and using contraception to denote when a child is conceived.[68] Julian Savulescu, a bioethicist and philosopher at Oxford University believes parents "should allow selection for non‐disease genes even if this maintains or increases social inequality", coining the term procreative beneficence to describe the idea that the children "expected to have the best life" should be selected.[69] The Nuffield Council on Bioethics said in 2017 that there was "no reason to rule out" changing the DNA of a human embryo if performed in the child's interest, but stressed that this was only provided that it did not contribute to societal inequality.[5]
Conversely, several concerns have been raised regarding the possibility of generating designer babies, especially with regard to the inefficiencies currently presented by the technologies. Bioethicist Ronald Green stated that although the technology was “unavoidably in our future”, he foresaw “serious errors and health problems as unknown genetic side effects in ‘edited’ children” arise.[70] Furthermore, Green warned against the possibility that “the well-to-do” could more easily access the technologies “..that make them even better off”. This concern regarding germline editing exacerbating a societal and financial divide is shared amongst other researches, with the chair of the Nuffield Bioethics Council Professor Karen Yeung stressing that if funding of the procedures “were to exacerbate social injustice, in our view that would not be an ethical approach”.[5]
Social and religious worries also arise over the possibility of editing human embryos. In a survey conducted by the Pew Research Centre, it was found that only a third of the Americans surveyed who identified as strongly Christian approved of germline editing.[71] Catholic leaders are in the middle ground. This stance is because, according to Catholicism, a baby is a gift from God, and Catholics believe that people are created to be perfect in God's eyes. Thus, altering the genetic makeup of an infant is unnatural. In 1984, Pope John Paul II addressed that genetic manipulation in aiming to heal diseases is acceptable in the Church. He stated that it “will be considered in principle as desirable provided that it tends to the real promotion of the personal well-being of man, without harming his integrity or worsening his life conditions”.[72] However, it is unacceptable if Designer Babies are used to create a super/superior race including cloning humans. The Catholic church rejects human cloning even if its purpose is to produce organs for therapeutic usage. The Vatican has stated that “The fundamental values connected with the techniques of artificial human procreation are two: the life of the human being called into existence and the special nature of the transmission of human life in marriage”[73]. According to them, it violates the dignity of the individual and is morally illicit.
In Islam, the positive attitude towards genetic engineering is based on the general principle that Islam aims at facilitating human life. However, the negative view comes from the process used to create a Designer baby. Oftentimes, it involves the destruction of some embryos. Muslims believe that “embryos already has a soul” at conception. [74]Thus, the destruction of embryos is against the teaching of the Qur’an, Hadith, and Shari’ah law, that teaches our responsibility to protect human life. To clarify, the procedure would be viewed as “acting like God/Allah”. With the idea, that parents could choose the gender of their child, Islam believes that humans have no decision to choose the gender, and that “gender selection is only up to God”[75].
Social aspects also raise concern, as highlighted by Josephine Quintavelle, director of Comment on Reproductive Ethics at Queen Mary University of London, who states that selecting children's traits is “turning parenthood into an unhealthy model of self-gratification rather than a relationship”.[76]
One major worry among scientists, including Marcy Darnovsky at the Center for Genetics and Society in California, is that permitting germline engineering for correction of disease phenotypes is likely to lead to its use for cosmetic purposes and enhancement.[5] Meanwhile, Henry Greely, a bioethicist at Stanford University in California, states that “almost everything you can accomplish by gene editing, you can accomplish by embryo selection”, suggesting the risks undertaken by germline engineering may not be necessary.[70] Alongside this, Greely emphasises that the beliefs that genetic engineering will lead to enhancement are unfounded, and that claims that we will enhance intelligence and personality are far off – “we just don’t know enough and are unlikely to for a long time – or maybe for ever”.
See also
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External links
- Bonsor, Kevin. Howstuffworks: How Designer Children Will Work
- Buchanan, Allen (2011). Beyond Humanity: The Ethics of Biomedical Enhancement. Oxford University Press.
| title = Why we Should Defend Gene Editing as Eugenics | publisher = Cambridge Quarterly of Healthcare Ethics | date = 2019 }}
- Savulescu, Julian. Designer Babies
- Stevens T, Newman S (2019). Biotech Juggernaut: Hope, Hype, and Hidden Agendas of Entrepreneurial Bioscience. New York, NY: Routledge.
- Strongin, Laurie Saving Henry, a non-fiction account of Strongin's pioneering use of IVF and PGD to have a healthy child whose cord blood could save the life of her son Henry