Objective To detecting the genetic etiology of a family with idiopathic pulmonary arterial hypertension and make gene diagnosis for the patient, so as to guide the targeted treatment and early intervention for the patient and her families. Methods The phenotype information of the family members was reviewed and their peripheral blood was collected for genomic DNA extraction. Exome sequencing was used to screen the mutations and proving the selected mutations by PCR-Sanger sequencing method. The pathogenicity of candidate mutation sites were searched through PubMed and related databases, and analyzed by protein function software. The judgement of pathogenicity was considered by clinical presentations and sequencing results of the patients based on Standards and guidelines for the interpretation of sequence variants revised by ACMG. Results At present, there was only one patient with pulmonary hypertension in this family, and other family members had no clinical manifestations of pulmonary hypertension. The female patient had BMPR2 gene c.1748dupA(p.Asn583Lysfs*6) heterozygous mutant. Her father and second son had BMPR2 gene c.1748dupA(p.Asn583Lysfs*6) heterozygous mutant, but none of the other members of the family had the mutation. Conclusions The heterozygous mutation of c.1748dupA (p.Asn583Lysfs*6) of BMPR2 gene is the genetic cause of the idiopathic pulmonary arterial hypertension patient, and the clinical significance of c.1748dupA(p.Asn583Lysfs*6) is pathogenic. The patient can be further diagnosed as pulmonary hypertension, primary 1 (PPH1) by gene diagnosis, and the mutant is novel and pathogenic for PPH1.
ObjectiveTo describe the research progress of silk-based biomaterials in peripheral nerve repair and provide useful ideals to accelerate the regeneration of large-size peripheral nerve injury. Methods The relative documents about silk-based biomaterials used in peripheral nerve regeneration were reviewed and the different strategies that could accelerate peripheral nerve regeneration through building bioactive microenvironment with silk fibroin were discussed. Results Many silk fibroin tissue engineered nerve conduits have been developed to provide multiple biomimetic microstructures, and different microstructures have different mechanisms of promoting nerve repair. Biomimetic porous structures favor the nutrient exchange at wound sites and inhibit the invasion of scar tissue. The aligned structures can induce the directional growth of nerve tissue, while the multiple channels promote the axon elongation. When the fillers are introduced to the conduits, better growth, migration, and differentiation of nerve cells can be achieved. Besides biomimetic structures, different nerve growth factors and bioactive drugs can be loaded on silk carriers and released slowly at nerve wounds, providing suitable biochemical cues. Both the biomimetic structures and the loaded bioactive ingredients optimize the niches of peripheral nerves, resulting in quicker and better nerve repair. With silk biomaterials as a platform, fusing multiple ways to achieve the multidimensional regulation of nerve microenvironments is becoming a critical strategy in repairing large-size peripheral nerve injury. Conclusion Silk-based biomaterials are useful platforms to achieve the design of biomimetic hierarchical microstructures and the co-loading of various bioactive ingredients. Silk fibroin nerve conduits provide suitable microenvironment to accelerate functional recovery of peripheral nerves. Different optimizing strategies are available for silk fibroin biomaterials to favor the nerve regeneration, which would satisfy the needs of various nerve tissue repair. Bioactive silk conduits have promising future in large-size peripheral nerve regeneration.