Objective To study the genetic diversity of different geographical populations of Houttuynia cordata in China.Methods The genetic diversity of 15 geographical populations of H.cordata from 13 provinces in China was estimated using amplified fragment length polymorphism(AFLP) markers.The data of amplified bands were analyzed by the software POPGENE and MEGA.Results The ten AFLP primers employed produced a total of 110 discernable and reproduceable amplified fragments.The percentage of polymorphic bands within different populations was 70.51%.Genetic diversity analysis showed that effective number of alleles(Ne) was 1.210,Nei′s gene diversity(H) was 0.119,and Shannon′s genetic diversity index(I) was 0.186.The coefficient of genetic distance was 0.008 9—0.181 8 among populations.A UPGMA dendrogram based on Nei′s(1972) genetic distance visualized that the 15 populations were grouped into three different clusters,Emei population was one individual cluster group and the other populations were grouped into two different clusters corresponding to the different geographical areas.Conclusion The genetic diversity within different geographical populations of H.cordata in China is plentiful.

Objective:To investigate the clinical characteristics of de novo malignancies (DNMs) after liver transplantation (LT) and to study the clinical management strategies.Methods:Adult LT recipients who were regularly followed-up in the Organ Transplantation Center, the Affiliated Hospital of Qingdao University from January 2005 to April 2021 were enrolled in this study. The clinical characteristics of DNMs were retrospectively analyzed. Of 601 LT recipients, there were 105 females and 496 males, aged (51.4±9.6) years old. They were divided into the DNMs group ( n=26) and the non-DNMs group ( n=575) according to whether there were DNMs on followed-up. Clinical data including age, sex, basic diseases before LT and operation time were collected. These patients were follow-up in outpatient clinics. Results:Twenty-six patients were diagnosed to develop DNMs after LT, but there were 28 DNMs (of which 2 patients were diagnosed to have DNMs twice). The incidence of DNMs after LT was 4.3% (26/601), the median time from LT to DNMs was 42 (20, 70) months, and the cumulative incidence rates of DNMs were 0.5%, 2.0%, 6.3%, 21.0% and 34.5% at 1, 3, 5, 10 and 15 years after LT, respectively. Among the 28 DNMs, digestive system tumors were most common, with 17 lesions (60.7%), followed by 3 lesions (11.1%) of lung cancer, 2 lesions (7.4%) of lymphoproliferative diseases, and 1 lesion (3.7%) of cervical cancer, thyroid cancer, soft palate cancer, eyelid cancer, laryngeal cancer, and prostate cancer. The follow-up time of 55.9 (36.6, 102.5) months in the DNMs group after LT was longer than the 33.4 (18.5, 58.9) months in the non-DNMs group ( P<0.001). The 1, 5, and 10 year survival rates of patients with DNMs after LT were 96.3%, 83.5%, and 49.8%, respectively. The 1, 5, and 10 year survival rates of patients with non-DNMs after LT were 94.5%, 77.7%, and 75.4%, respectively. There was no significant difference in the cumulative survival rates between the two groups (log rank=0.402, P=0.526). Conclusion:The incidence of DNMs in LT recipients was 4.3%. The majority of them were digestive system tumors. Early diagnosis and treatment of DNMs significantly improved the prognosis and quality of life of these patients.