Biópsia embrionária: qual a melhor escolha? / Embryo biopsy: what is the best choice?

Introdução: a biópsia embrionária tem como objetivo selecionar embriões geneticamente normais. Essa seleção ocorre por meio de testes genéticos pré-implantacionais. Espera-se, com isso, uma diminuição dos riscos de doenças genéticas e um aumento das taxas de implantação em fertilização in vitro. Objetivo: verificar, por meio de revisão bibliográfica, qual técnica de biópsia embrionária é considerada mais apropriada para feitura de testes genéticos pré-implantacionais. Método: pesquisa bibliográfica, na forma de revisão de publicações científicas, por meio das redes US National Library of Medicine (Pubmed), Literatura Latino-Americana e do Caribe em Ciências da Saúde (Lilacs), Google Acadêmico e Biblioteca Virtual em Saúde (BVS). Resultados e conclusão: existem três maneiras de efetuar a biópsia para reprodução humana assistida. A primeira consiste em retirar o primeiro e/ou o segundo corpúsculo polar estruído pelo oócito. Também se pode fazer a biópsia a partir de um blastômero do embrião em estágio de clivagem ou usar cinco a dez células do trofoectoderma de blastocisto. Normalmente as técnicas usadas para o diagnóstico são PCR, Fish, CGH array e SNP array, entre outras. Acredita-se que a biópsia de blastocistos é a melhor técnica para manter o potencial de implantação embrionária. Essa tendência se justifica por causa da maior quantidade de material genético disponível em fase avançada de desenvolvimento embrionário. Admite-se que nessa fase a incidência de mosaicismo seja menor em relação à biópsia de blastômeros, com consequente aumento na eficácia dos testes genéticos. Outra questão importante é que na biópsia de blastocistos as células são retiradas do trofoectoderma, enquanto que na biópsia em estágio de clivagem a remoção de um blastômero pode prejudicar o desenvolvimento embrionário.

Introduction: the embryo biopsy aims to select genetically normal embryos. This selection occurs through pre- implantation genetic testing. It is expected the reduction of risk ofgenetic disorders and increase implantation rates in IVF.Objective: to verify, through bibliographical revision, which embryo biopsy technique is considered more suitable for pre-implantation genetic diagnosis. Method: bibliographical research, in the form of literary review of scientific publications via networks, US National Library of Medicine (Pubmed), Latin-American Literature and Caribbean Health Sciences (Lilacs), Google Scholar and Virtual Health Library. Results and conclusion: there are three ways to perform the biopsy on assisted human reproduction.The first one consists in removing the 1st and/or 2nd polar body (if there wasfertilization). You can also perform the biopsy from the one blastomere of embryo cleavage stage or use 5-10 trophoectoderm cells blastocyst. Usually the techniques used for diagnosticpurpose are PCR, Fish, CGH array, SNP array and others. Nowadays it is believed that blastocyst biopsy is the best technique in order to maintain the embryonic implantation. This tendency is justified by the larger amount of genetic material available in an advancedstage of embryonic development. It is assumed that in this stage the incidence of mosaicism is reduced with the consequent increase in the effectiveness of genetic testing. Another important question is that the blastocyst biopsy cells are removed from the trophoectoderm while inbiopsy incleavage stage, the removal of one blastomere can impair embryonicdevelopment.

A successful strategy for Preimplantation Genetic Diagnosis of beta-thalassemia and simultaneous detection of Down's syndrome using multiplex fluorescent PCR.

OBJECTIVES: Preimplantation Genetic Diagnosis (PGD) is an alternative to prenatal diagnosis providing couples the chance to start a pregnancy with an unaffected fetus. The objective of the present study was to develop and apply quick, sensitive and accurate single cell PCR protocols for PGD of beta-thalassemia and Down's syndrome detection. MATERIAL AND METHOD: Two couples carrying beta-thalassemia codon41-42 mutation underwent routine IVF procedures. Embryo biopsy was performed on Day-3 post-fertilisation and single cell multiplex fluorescent PCR was employed for mutation analysis, contamination detection and diagnosis of trisomy 21 cases. RESULTS: Seventeen embryos were tested in two clinical PGD cycles. This resulted in the first birth following PGD for a single gene disorder in Thailand and South East Asia, confirmed by prenatal testing. Two embryos were shown to be affected by Down's syndrome. CONCLUSION: Successful strategy for PGD of beta-thalassemia and Down's syndrome detection using multiplex fluorescent PCR was introduced.

Radiobiological effects of low doses of tritiated water on developing mouse cerebellum from 17th day post-coitum.

Pregnant Swiss albino mice were maintain on tritiated drinking water of the activity of 111 and 11.1 kBq/ml after a priming injection of 74 and 7.4 kBq/ml body water respectively from 17th day of gestation till parturition. Animals were autopsied on 1, 2, 3, 4, 5 and 6 weeks postpartum and studied for cerebellar vulnerability. Cerebellum suffered from radiopathological changes in 1, 2 and 3 weeks age groups of mice in terms of degeneration and loss of Purkinje cells leading to formation of empty basquets, vacuolation in molecular layer and interfoliar connective tissue and pycnosis in granule cells of granular cell layer at 11.1 kBq dose level. Mice of 4, 5 and 6 weeks age groups, being relatively radioresistant, showed lesser changes in comparison with 1 to 3 week old mice. Though, the nature of the damage remained the same, it tended to intensify at 111 kBq dose thereby reflecting a dose dependent variation.