Lung Cancer Risk Attributable to Active Smoking in China: A Systematic Review and Meta-Analysis.

Objective: No consensus exists on the relative risk ( RR) of lung cancer (LC) attributable to active smoking in China. This study aimed to evaluate the unified RR of LC attributable to active smoking among the Chinese population. Methods: A systematic literature search of seven databases was conducted to identify studies reporting active smoking among smokers versus nonsmokers in China. Primary articles on LC providing risk estimates with their 95% confidence intervals ( CIs) for "ever" "former" or "current" smokers from China were selected. Meta-analysis was used to estimate the pooled RR of active smoking. Results: Forty-four unique studies were included. Compared with that of nonsmokers, the pooled RR (95% CI) for "ever" "former" and "current" smokers were 3.26 (2.79-3.82), 2.95 (1.71-5.08), and 5.16 (2.58-10.34) among men, 3.18 (2.78-3.63), 2.70 (2.08-3.51), and 4.27 (3.61-5.06) among women, and 2.71 (2.12-3.46), 2.66 (2.45-2.88), and 4.21 (3.25-5.45) in both sexes combined, respectively. Conclusion: The RR of LC has remained relatively stable (range, 2-6) over the past four decades in China. Early quitting of smoking could reduce the RR to some extent; however, completely refraining from smoking is the best way to avoid its adverse effects.

The Association between Exposure to Second-Hand Smoke and Disease in the Chinese Population: A Systematic Review and Meta-Analysis.

Objective: To analyze the association between exposure to second-hand smoke (SHS) and 23 diseases, categorized into four classifications, among the Chinese population. Methods: We searched the literature up to June 30, 2021, and eligible studies were identified according to the PECOS format: Participants and Competitors (Chinese population), Exposure (SHS), Outcomes (Disease or Death), and Study design (Case-control or Cohort). Results: In total, 53 studies were selected. The odds ratio (OR) for all types of cancer was 1.79 (1.56-2.05), and for individual cancers was 1.92 (1.42-2.59) for lung cancer, 1.57 (1.40-1.76) for breast cancer, 1.52 (1.12-2.05) for bladder cancer, and 1.37 (1.08-1.73) for liver cancer. The OR for circulatory system diseases was 1.92 (1.29-2.85), with a value of 2.29 (1.26-4.159) for stroke. The OR of respiratory system diseases was 1.76 (1.13-2.74), with a value of 1.82 (1.07-3.11) for childhood asthma. The original ORs were also shown for other diseases. Subgroup analyses were performed for lung and breast cancer. The ORs varied according to time period and were significant during exposure in the household; For lung cancer, the OR was significant in women. Conclusion: The effect of SHS exposure in China was similar to that in Western countries, but its definition and characterization require further clarification. Studies on the association between SHS exposure and certain diseases with high incidence rates are insufficient.

[Human/mouse chimeric anti-CD20 monoclonal antibody enhances antigen presentation in dendritic cells and induces anti-lymphoma CTL effects].

In order to investigate the cellular immunoresponses mediated by chimeric anti-CD20 monoclonal antibody (anti-CD20 McAb) through dendritic cells (DCs), mononuclear cells were isolated from human peripheral blood (PBMNC) and DCs from PBMNCs in vitro were generated with normal methods. Human CD20 positive lymphoma cell line-Raji cells were treated with different methods including treatment with anti-CD20 McAb (group R), treatment with heat-induced apoptosis (group A) and treatment with anti-CD20 McAb+heat-induced apoptosis (group R+A), then Raji cells treated with above-mentioned methods as tumor antigen were loaded on DCs. The phagocytosis of DCs to tumor antigen was observed by transmission electron microscope (TEM), the auto-mixed lymphocyte reaction was performed with antigen-primed DCs, the release of INF-gammafrom effector cells was detected by ELISPOT, the killing of effector cells on Raji cells was assayed by MTT. The results showed that under TEM, no pronounced phagocytosis of DCs was seen in group R, while the phagocytosis of apoptotic bodies could be easily seen in group A and the more cell fraqments were observed in group R+A. The FCM indicated that the expressions of CD80, CD86 and HLA-DR on DCs in 3 experimental groups were higher than those in group control (p<0.05), while expression positive rate in group R+A was higher than those in group R and A (p<0.05). The detection of lymphocyte surface antigen revealed that proportions of CD8+ cells in all experimental groups were higher than those in group control (p<0.05), count of CD56+ cells in group R and R+A increased, as compared with group A and control, difference was significant (p<0.05). ELISPOT assay indicated that amount of cells releasing IFN-gamma in all experimental groups was higher than that in group control, and also number of spots in group R+A significantly higher than that in other groups at effector-targetor ratio=1:10 (p<0.05). The results of killing assay demonstrated that killing rate on Raji cells in all experimental groups increased as compared with group control (p<0.05), while killing rate in group R+A was higher than that in group R and A. It is concluded that anti-CD20 McAb can mediate DC to induce cellular immunoresponse against lymphoma, that is, to stimulate and amplify specific CTLs and NK cells. Anti-CD20 McAb combined with DCs primed by heat-stressed tumor cells as antigen can further enhance cellular immunoresponse against lymphoma.