Objectives China is one of the 22 tuberculosis (TB) high-burden countries in the world. As TB is a major public health problem in China, spatial analysis could be applied to detect geographic distribution of TB clusters for targeted intervention on TB epidemics. Methods Spatial analysis was applied for detecting TB clusters on county-based TB notification data in the national notifiable infectious disease case reporting surveillance system from 2005 to 2011. Two indicators of TB epidemic were used including new sputum smear-positive (SS+) notification rate and total TB notification rate. Global Moran’s I by ArcGIS was used to assess whether TB clustering and its trend were significant. SaTScan software that used the retrospective space-time analysis and Possion probability model was utilized to identify geographic areas and time period of potential clusters with notification rates on county-level from 2005 to 2011. Results Two indicators of TB notification had presented significant spatial autocorrelation globally each year (p<0.01). Global Moran’s I of total TB notification rate had positive trend as time went by (t=6.87, p<0.01). The most likely clusters of two indicators had similar spatial distribution and size in the south-central regions of China from 2006 to 2008, and the secondary clusters in two regions: northeastern China and western China. Besides, the secondary clusters of total TB notification rate had two more large clustering centers in Inner Mongolia, Gansu and Qinghai provinces and several smaller clusters in Shanxi, Henan, Hebei and Jiangsu provinces. Conclusion The total TB notification cases clustered significantly in some special areas each year and the clusters trended to aggregate with time. The most-likely and secondary clusters that overlapped among two TB indicators had higher TB burden and risks of TB transmission. These were the focused geographic areas where TB control efforts should be prioritized.
References
[1]
World Health Organization (2012) Global tuberculosis report 2012. Available: . . Accessed 2012 Jun.
[2]
Wang LX (2012) Status analysis of Tuberculosis prevention and control, China. Chinese Journal of Public Health 28: 413-414 [ Chinese].
[3]
Liu Y, Li X, Wang W, Li Z, Hou M et al. (2012) Investigation of space-time clusters and geospatial hot spots for the occurrence of tuberculosis in Beijing. Int J Tuberc Lung Dis 16: 486-491. doi:10.5588/ijtld.11.0255. PubMed: 22325066.
[4]
Maciel EL, Pan W, Dietze R, Peres RL, Vinhas SA et al. (2010) Spatial patterns of pulmonary tuberculosis incidence and their relationship to socio-economic status in Vitoria, Brazil. Int J Tuberc Lung Dis 14: 1395-1402. PubMed: 20937178.
[5]
Wang LX, Cheng SM, Chen MT, Zhao YL, Zhang H et al. (2012) The fifth national tuberculosis epidemiological survey in 2010. Chinese Journal of Antituberculosis 34: 485-508 [ Chinese].
[6]
Carsten FD, Jana MM, Miguel BA, Roger B, Janine B et al. (2007) Methods to account for spatial autocorrelation in the analysis of species distributional data: a review. Ecography 30: 609-628. doi:10.1111/j.2007.0906-7590.05171.x.
Palma L, Beja P, Rodrigues M (1999) The use of sighting data to analyse Iberian lynx habitat and distribution. Journal of Applied Ecology 36: 812-824. doi:10.1046/j.1365-2664.1999.00436.x.
[9]
Griffith DA, Peres-Neto PR (2006) Spatial modeling in ecology: the flexibility of eigenfunction spatial analyses. Ecology 87: 2603-2613. Available online at: doi:10.1890/0012-9658(2006)87[2603:SMIET?F]2.0.CO;2. PubMed: 17089668.
[10]
Roza DL, Caccia-Bava MC, Martinez EZ (2012) Spatio-temporal patterns of tuberculosis incidence in Ribeirao Preto, State of Sao Paulo, southeast Brazil, and their relationship with social vulnerability: a Bayesian analysis. Rev Soc Bras Med Trop 45: 607-615.
[11]
Randremanana RV, Sabatier P, Rakotomanana F, Randriamanantena A, Richard V (2009) Spatial clustering of pulmonary tuberculosis and impact of the care factors in Antananarivo City. Trop Med Int Health 14: 429-437. PubMed: 19228353.
[12]
Liu Y, Jiang S, Wang R, Li X, Yuan Z et al. (2011) Spatial epidemiology and spatial ecology study of worldwide drug-resistant tuberculosis. Int J Health Geogr 10: 50. doi:10.1186/1476-072X-10-50. PubMed: 21812998.
[13]
Wang L, Wang Y, Jin S, Wu Z, Chin DP et al. (2008) Emergence and control of infectious diseases in China. Lancet 372: 1598-1605. doi:10.1016/S0140-6736(08)61365-3. PubMed: 18930534.
[14]
Yin F, Feng Z, Li X (2012) Spatial analysis of county-based gonorrhoea incidence in mainland China, from 2004 to 2009. Sex Health 9: 227-232. doi:10.1071/SH11052. PubMed: 22697139.
[15]
Chinese Information System for Infectious Diseases Control and Prevention on April 1st (2004). Available: . . Accessed 2004 April 2.
[16]
Yan WR, Nie SF, Xu B, Dong HJ, Palm L et al. (2012) Establishing a web-based integrated surveillance system for early detection of infectious disease epidemic in rural China: a field experimental study. BMC Med Inform Decis Mak 12: 4. doi:10.1186/1472-6947-12-4. PubMed: 22305256.
[17]
The Central People's Government of the Peoples Republic of China. Available: . Accessed 2013.
[18]
National Bureau of Statistics of China. Available: . Accessed 2006.
[19]
Huo XN, Li H, Sun DF, Zhou LD, Li BG (2012) Combining Geostatistics with Moran's I Analysis for Mapping Soil Heavy Metals in Beijing, China. Int J Environ Res Public Health 9: 995-1017. doi:10.3390/ijerph9030995. PubMed: 22690179.
[20]
How Spatial Autocorrelation: Moran's I (Spatial Statistics) works. Available: . 's%20I%20(Spatial%20Statistics)%20works. Accessed 2009 Jan 28.
[21]
Huo XN, Zhang WW, Sun DF, Li H, Zhou LD et al. (2011) Spatial pattern analysis of heavy metals in Beijing agricultural soils based on spatial autocorrelation statistics. Int J Environ Res Public Health 8: 2074-2089. doi:10.3390/ijerph8062074. PubMed: 21776217.
Kulldorff M (2010) SaTScan User Guide for version 9. In: Institute NC, editor. 109 p.
[24]
Tostmann A, Kik SV, Kalisvaart NA, Sebek MM, Verver S et al. (2008) Tuberculosis transmission by patients with smear-negative pulmonary tuberculosis in a large cohort in the Netherlands. Clin Infect Dis 47: 1135-1142. doi:10.1086/591974. PubMed: 18823268.
[25]
Reichler MR, Reves R, Bur S, Thompson V, Mangura BT et al. (2002) Evaluation of investigations conducted to detect and prevent transmission of tuberculosis. JAMA 287: 991-995. doi:10.1001/jama.287.8.991. PubMed: 11866646.
[26]
Zhang ZJ, Zhu R, Bergquist R, Chen DM, Chen Y et al. (2012) Spatial comparison of areas at risk for schistosomiasis in the hilly and mountainous regions in the People's Republic of China: evaluation of the long-term effect of the 10-year World Bank Loan Project. Geospat Health 6: 205-214. PubMed: 22639122.
[27]
Zhang Y, Liu QY, Luan RS, Liu XB, Zhou GC et al. (2012) Spatial-temporal analysis of malaria and the effect of environmental factors on its incidence in Yongcheng, China, 2006-2010. BMC Public Health 12: 544. doi:10.1186/1471-2458-12-544. PubMed: 22823998.
[28]
Coleman M, Mabuza AM, Kok G, Coetzee M, Durrheim DN (2009) Using the SaTScan method to detect local malaria clusters for guiding malaria control programmes. Malar J 8: 68. doi:10.1186/1475-2875-8-68. PubMed: 19374738.
[29]
Dietz NA, Sherman R, Mackinnon J, Fleming L, Arheart KL et al. (2011) Toward the identification of communities with increased tobacco-associated cancer burden: Application of spatial modeling techniques. J Carcinog 10: 22. doi:10.4103/1477-3163.85184. PubMed: 22013392.
[30]
Touray K, Adetifa IM, Jallow A, Rigby J, Jeffries D et al. (2010) Spatial analysis of tuberculosis in an urban west African setting: is there evidence of clustering? Trop Med Int Health 15: 664-672. doi:10.1111/j.1365-3156.2010.02533.x. PubMed: 20406427.
