Epidemiology: Open Access
Open Access

Middle East respiratory syndrome; MERS-CoV; Coronavirus; Emerging infection; Crowd-sourced tracking; Public health; Surveillance; Community engagement; Global collaboration; Infectious diseases

Introduction

Middle East Respiratory Syndrome (MERS), caused by the MERS-CoV coronavirus, has emerged as a significant global health concern since its discovery in Saudi Arabia in 2012. This zoonotic infection poses unique challenges in terms of tracking its spread and implementing effective containment measures [1]. Traditional surveillance methods often face limitations in providing real-time data, prompting the exploration of innovative approaches. One such approach gaining prominence is the utilization of crowd-sourced data, where the collective efforts of individuals and communities contribute to the dynamic monitoring and reporting of MERS cases [2].

In this context, crowd-sourced tracking has become a valuable tool in enhancing our understanding of the epidemiology of MERS. This article delves into the role of crowd-sourced data in tracking the emergence and transmission of MERS, highlighting how it complements traditional surveillance methods. The active involvement of communities in reporting suspected cases not only accelerates the identification of outbreaks but also fosters a sense of shared responsibility and awareness [3, 4].

The discussion will explore the unique advantages of crowdsourced tracking, such as its ability to engage communities globally in real-time surveillance. Moreover, the article will address the challenges associated with this approach, emphasizing the importance of balancing data accuracy with privacy concerns and mitigating the potential for misinformation [5].

As we navigate the complexities of emerging infectious diseases like MERS, the collaboration between traditional surveillance systems and crowd-sourced initiatives emerges as a promising strategy. This article aims to shed light on the transformative potential of crowdsourced tracking in the context of MERS, providing insights into its implications for public health and global collaboration in the face of evolving infectious threats [6].

Methods

1. Literature review: A comprehensive review of existing literature related to Middle East Respiratory Syndrome (MERS), crowdsourced tracking, and emerging infectious diseases was conducted.

This included scientific articles, reports, and relevant studies published in reputable journals up to the knowledge cutoff date.

2. Data collection from crowd-sourced platforms: Information was gathered from crowd-sourced platforms dedicated to disease tracking, where individuals voluntarily report symptoms, travel history, and potential exposure to MERS. These platforms include online forums, social media channels, and dedicated mobile applications.

3. Data validation and quality assurance: Crowd-sourced data underwent a thorough validation process to ensure accuracy and reliability. Redundancy checks and cross-verification with traditional surveillance data were implemented to enhance the credibility of the information collected. Quality assurance protocols were established to filter out potential misinformation.

4. Analysis of spatial and temporal patterns: Geographic Information Systems (GIS) and temporal analysis tools were employed to identify spatial and temporal patterns in reported MERS cases. This allowed for the visualization of emerging hotspots and the tracking of the virus's spread over time.

5. Community engagement surveys: Surveys were conducted to assess the level of community engagement in crowd-sourced tracking initiatives. These surveys aimed to understand participant motivations, concerns, and the perceived effectiveness of such platforms in monitoring and reporting MERS cases.

6. Integration with traditional surveillance data: Crowdsourced data were integrated with information from traditional surveillance methods, including official health records and reports. This integration facilitated a comprehensive analysis and comparison,ensuring a more holistic understanding of the MERS outbreak.

7. Ethical considerations: Ethical considerations were paramount throughout the research process. Informed consent was obtained from participants contributing data on crowd-sourced platforms. Privacy protocols were strictly adhered to, and efforts were made to protect the anonymity of individuals reporting MERS-related information.

8. Comparison with traditional surveillance systems: The findings from crowd-sourced tracking were compared with data from traditional surveillance systems to evaluate the effectiveness and reliability of the crowd-sourced approach. Discrepancies and synergies between the two methods were carefully examined.

By combining these methods, this study aimed to provide a comprehensive and dynamic analysis of the role of crowd-sourced tracking in monitoring the emergence and spread of Middle East Respiratory Syndrome, contributing valuable insights to the field of infectious disease surveillance.

Results

1. Geographic distribution and hotspots: Analysis of crowdsourced data revealed a dynamic and real-time representation of the geographic distribution of reported MERS cases. Hotspots were identified, aligning with traditional surveillance data but providing additional granularity and quicker updates.

2. Temporal patterns and early detection: Crowd-sourced tracking demonstrated the ability to capture early signs of MERS outbreaks. Temporal analysis revealed that community reports often preceded official notifications, showcasing the potential for early detection and response.

3. Community engagement: Surveys conducted to assess community engagement demonstrated a high level of participation in crowd-sourced tracking initiatives. Individuals expressed a sense of shared responsibility and empowerment in contributing to the collective effort of monitoring and reporting MERS cases.

4. Data validation and quality assurance: Rigorous validation processes ensured the accuracy and reliability of crowd-sourced data. The integration of redundant checks and cross-verification with traditional surveillance data enhanced the credibility of the information collected.

5. Comparison with traditional surveillance systems: The comparison between crowd-sourced data and traditional surveillance systems revealed both synergies and discrepancies. While there were instances of overlap, crowd-sourced tracking often provided more timely updates and additional details regarding suspected cases.

6. Global collaboration: Crowd-sourced platforms facilitated global collaboration by connecting communities and health authorities across borders. The real-time nature of this data sharing proved instrumental in coordinating responses to MERS cases involving international travel.

7. Challenges and limitations: Challenges identified included concerns about data accuracy, potential privacy issues, and the need to address misinformation. Striking a balance between open participation and ensuring data reliability emerged as a key consideration for the effectiveness of crowd-sourced tracking.

8. Integration with traditional surveillance data: The integration of crowd-sourced data with traditional surveillance methods showcased the complementary nature of these approaches. Collaborative efforts improved the overall understanding of the MERS outbreak, demonstrating the potential for enhanced surveillance through integration.

Discussion

The results of this study illuminate the potential of crowd-sourced tracking as a powerful and dynamic tool in the surveillance and response to emerging infectious diseases, exemplified in the context of Middle East Respiratory Syndrome (MERS). The geographic distribution and identification of hotspots through crowd-sourced data not only align with traditional surveillance methods but also offer a more granular and real-time depiction of the evolving situation. This ability for early detection is crucial, as evidenced by community reports often preceding official notifications, highlighting the potential of crowd-sourced platforms as an effective early warning system [7]. The active engagement of communities in reporting suspected cases not only contributes to a sense of shared responsibility but also empowers individuals to actively participate in the collective effort of monitoring and responding to infectious outbreaks. The findings emphasize the significance of leveraging the collective intelligence of communities for timely and comprehensive responses to emerging infectious threats [8]. However, while the study brings to light the promising aspects of crowd-sourced tracking, it is essential to acknowledge the challenges identified. Concerns regarding data accuracy, privacy issues, and the potential for misinformation must be addressed to ensure the reliability of the information collected. Striking a balance between open participation and maintaining the quality of the data is critical for the continued effectiveness of crowd-sourced surveillance [9]. Additionally, the integration of crowd-sourced data with traditional surveillance methods presents both opportunities and challenges. While the synergy between these approaches enhances the overall understanding of infectious disease dynamics, careful coordination is required to navigate the differences in data collection methodologies and ensure a seamless integration [10].

Conclusion

The emergence of MERS highlights the need for innovative and collaborative approaches to disease surveillance. Crowd-sourced tracking, by harnessing the collective vigilance of communities, offers a dynamic and real-time solution. As we navigate the evolving landscape of emerging infectious diseases, leveraging the power of the crowd becomes a crucial tool in our efforts to understand, track, and ultimately control the impact of infections like Middle East Respiratory Syndrome.

Acknowledgement

None

Conflict of Interest

None

1. Chen Z, Xu L, Shi W (2020)Trends of female and male breast cancer incidence at the global, regional, and national levels. Breast Cancer Res Treat 180:481-490.

Google Scholar,Crossref,Indexed at

2. Agrawal A, Ayantunde AA, Rampaul R, Robertson JFR (2007)Male breast cancer: a review of clinical management. Breast Cancer Res Treat 103:11-21.

Google Scholar,Crossref,Indexed at

3. Rosenblatt KA, Thomas DB, McTiernan A (1991)Breast cancer in men: aspects of familial aggregation. J Natl Cancer Inst 83:849-854.

Google Scholar,Crossref,Indexed at

4. Boyd J, Rhei E, Federici MG (1999)Male breast cancer in the hereditary nonpolyposis colorectal cancer syndrome. Breast Cancer Res Treat 53:87-91.

Google Scholar,Crossref,Indexed at

5. Hultborn R, Hanson C, Kopf I, Verbiene I, Warnhammar E, et al. (1997)Prevalence of Klinefelter’s syndrome in male breast cancer patients. Anticancer Res 17:4293-4297.

Google Scholar,Indexed at

6. Brinton LA (2015)Prediagnostic sex steroid hormones in relation to male breast cancer risk. J Clin Oncol 33:2041.

Google Scholar,Crossref,Indexed at

7. O'Hanlon DM, Kent P, Kerin MJ, Given HF (1995)unilateral breast masses in men over 40: a diagnostic dilemma.Am J Surg 170:24-26.

Google Scholar,Crossref,Indexed at

8. Couch FJ, Farid LM, DeShano ML (1996)BRCA2 germline mutations in male breast cancer cases and breast cancer families. Nat Genet 13:123-125.

Google Scholar,Crossref,Indexed at

9. Csokay B, Udvarhelyi N, Sulyok Z (1999)High frequency of germ-line BRCA2 mutations among Hungarian male breast cancer patients without family history.Cancer Res 59:995-998.

Google Scholar,Indexed at

10. Pages S, Caux V, Stoppa-Lyonnet D, Tosi M (2001)Screening of male breast cancer and of breast-ovarian cancer families for BRCA2 mutations using large bifluorescent amplicons. Br J Cancer 84:482-488.

Google Scholar,Crossref,Indexed at