Document Type : Original Article
Authors
1 Clinical Pathology Department, Faculty of Medicine, Al-Azhar University
2 Microbiology Department, Faculty of Medicine, Ain Shams University
Abstract
Keywords
HEPATITIS C VIRUS (HCV) CORE ANTIGEN AS AN ALTERNATIVE TO PCR FOR HCV, RNA QUANTIFICATION TO EARLY DIAGNOSIS OF HCV INFECTION AMONG BLOOD DONORS
By
Mohamed Aleraky Saleh, Mahmoud Ali Saudi
and Omima Sayed Mohamed*
Clinical Pathology Department, Faculty of Medicine, Al-Azhar University
and Microbiology Department, Faculty of Medicine, Ain Shams University*
ABSTRACT
Background: Safety blood transfusion is based on reliable donor screening for transmissible infections such as the hepatitis C virus (HCV) infection. HCV-RNA by polymerase chain reaction (PCR) test is a gold standard test for HCV infection but with three major limitations: liability of RNA molecules, higher costs, and longer turnaround time as compared with HCV core antigen (HCVcAg) testing. Objective: To evaluate HCV core Ag as an alternative to PCR for HCV RNA to early diagnosis of HCV infection among blood donors. Patients and Methods: 4222 blood donors collected between March 2015 and July 2016 at Blood Bank Center of Najran Hospitals, Southwestern Saudia Arabia. Anti-HCV, HBsAg, syphilis and HIV were screened by third generation ELISA. Those reactive to HbsAg, syphilis and/or HIV were excluded. HCV core Ag and HCV RNA by RT-PCR were performed on 76 positive HCV-Ab sera. Results: Among total 4222 blood donors (3837 males (90.88%) and 385 females (9.12%)), 76 (1.8%) were positive for HCV-Ab (72 males; 94.74% and 4 females; 5.26%). HCV core Ag was ≥ 11 fmol/L in 65 cases (85.53%) of HCV Ab positive patients (61 males; 93.85% and 4 females; 6.15%), 3 cases with HCVcAg levels in grey zone (3-11 fmol/L) and 8 cases with HCVcAg ≤ 3 fmol/L all of both were males. HCV RNA was detected in 71/76 (93.42%) of donors with positive HCV-Ab and in 3 of 8 (37.5%) of those with positive HCV-ab and negative HCVcAg. HCVcAg has sensitivity, specificity, PPV and NPV of 97.14, 100, 100 and 99.76 values respectively at a cutoff 2.82 fmol/L compared to HCV RNA test. Conclusion: Higher sensitivity and specificity of HCVcAg with rapid turn around time of the results, and its lower price suggested that can be used alternatively to HCV RNA test in early diagnosis of HCV infection.
Keywords: HCV infection, HCV core Ag, Immunoassay, Virological marker.
INTRODUCTION
Hepatitis C virus (HCV) is a global pathogen, infecting more than 185 million individuals, with global seroprevalence estimated at 2.8% (2.6 to 3.1%), and more than 1 million new cases reported annually (Mastro et al., 2016).
Detection of blood borne viruses by conventional serology tests depend upon levels of viral specific antibodies, virus antigens and sensitivity and specificity of serology method used. During early infection, the virus is present in the blood of the infected individual and may be transmitted to the recipient of this infected blood even though the conventional serological test is negative (Elbjeirami et al., 2015).
Diagnosis of HCV infection requires the detection of anti-HCV virus antibodies with confirmation of positive results using polymerase chain reaction (PCR). HCV RNA by PCR can detect HCV virus as early as 15-20 days post exposure and at a very low level of viremia. It is a reliable method but needs technical skill. It is time intensive and more expensive, and may result in false positivity because of contamination (Abd El-Reheem et al., 2016).
HCV core Ag (HCVcAg) tests have been shown to detect HCV infection 45 days earlier than HCV-Ab screening test, and 1-2 days following the detection of HCV RNA in the serum. Moreover, it has been reported that detection of HCVcAg can decrease the window period interval to 23.9 days (Zhang et al., 2007).
HCVcAg estimation by automated chemiluminescent immunoassay has deve-loped with higher sensitivity to overcome shortcomings of the HCVcAg ELISA assays (Mederacke et al., 2009; Morota et al., 2009 and Abd El-Reheem et al., 2016).
The present study was designed to assess whether the HCVcAg test by chemiluminescent immunoassay is a good alternative to PCR for the early diagnosis of HCV infection, particularly in the acute phase of the illness and during which the infection can be missed in a substantial number of blood donors, if anti-HCV Ab testing is employed alone.
PATIENTS AND METHODS
This observational study was carried out on a cross sectional sample of voluntary 4222 blood donors (3837 males (90.88%) and 385 females (9.12%) collected between March 2015 and July 2016 at Blood Bank Center of Najran Hospitals, Southwestern Saudia Arabia. Of these donors, 76 (1.8%) were positive for HCV-Ab (72 males; 94.74% and 4 females; 5.26%).
A written consent was obtained for blood donation and permission to perform relevant tests on blood. After initial interview and mini-medical examination, demographic data were recorded, and donors were accepted for blood donation. Blood samples were withdrawn from each blood unit during donation under strict aseptic conditions for blood grouping, cross-match, anti-body screening, syphilis serology, malaria slide examination, anti-HCV, HBsAg, and HIV were taken. Anti-HCV, HBsAg and HIV were screened by third generation ELISA. Those reactive to HBsAg, HIV, syphilis serology or malaria were excluded.
Three ml from each positive HCV-Ab blood unit was added to a sterile vacutainer tube and then separated by centrifugation in PCR unit under strict sterile conditions and serum was stored at -70 °C to be used for PCR and HCVcAg testing.
Anti-HCV antibody screening
Screening for anti-HCV antibody was performed using Murex anti-HCV (version 4.0), (DiaSorin S.p.A., Dartford, UK) ELISA kits on Evolis system (Bio-Rad® Technology INC. USA).
Anti-HCV antibody test results of ≥ 1.00 signal-to cut- off (s/co) were considered reactive, results of <0.90 s/co were considered non-reactive, and results of ≥ 0.90 s/co and <1.00 s/co were considered equivocal (gray zone) according to the manufacturers' instructions, and were confirmed by repeating the sample in duplicate using the same kit, and then testing it using HCVcAg and PCR-HCV RNA tests.
HCVcAg determination:
HCVcAg was measured using Abbott Architect HCV Chemiluminescenat Microparticle Immunoassay (CMIA) on Architect i2000 system (Abbott Laboratories, Abbott Park, IL, USA).
HCVcAg test results of <3.00 femtomole/liter (fmol/L) were considered nonreactive. Values between ≥3.00 fmol/L and ≤11.00 fmol/L were considered grey zone, and results of ≥11.00 fmol/L were considered reactive (1.0 fmol/L of HCVcAg equals to 0.02 pg/mL) according to the manufacturers' instructions.
HCV RNA by PCR determination:
Viral RNA was extracted from all serum HCV-Ab positive samples using AmpliPrep/COBAS® TaqMan® HCV Test Kit on Mx3000P QPCR System (Agilent Technologies, California, USA).
The lower limit of detection of this assay was 12 IU/ml, with a linear range between 43 x 106 and 69 x 106 IU/ml. Each specimen was analyzed in duplicate and the mean value was reported as the HCV RNA level in the serum. A known quantity of internal quality control serum was included in each preparation of RT-PCR. The cycle conditions of RT-PCR included 95 ◦C for 10 min, followed by a further 40 cycles at 95 ◦C for 10s, 58 ◦C for 15s, and 72 ◦C for 10s. According to the manufacturers' instructions, HCV RNA measures of <101 International Unit/mililiter (IU/ml) were considered as low-level viremia, and values of >101 IU/ml were considered as positive.
Statistical analysis
Statistical analyses were performed using IBM SPSS Statistics version 20.0 (SPSS Inc., Chicago, IL, United States). Descriptive variables were presented as numbers, percentages mean±standard deviation (SD). Sensitivity and specificity as well as receiver operating characteristic (ROC) curve analysis were applied to HCV Ag value compared to HCV RNA. Correlations between different parameters calculated by the Spearman test. p<0.05 was considered statistically significant.
RESULTS
Among total 4222 blood donors (3837 males (90.88%) and 385 females (9.12%), 76 (1.8%) were positive for HCV-Ab (72 males; 94.74% and 4 females; 5.26%), with age between 26 and 50 years (mean 37.01±5.32 years). HCVcAg varied between 0.23-2072 fmol/L with mean 473.78±539.89 and HCV RNA ranged between 0.0-6.94 log10 IU/mL with mean 6.12±6.30 log 10 (Table 1).
As regard to HCVcAg, it was positively determined (≥ 11 fmol/L) in 65 cases (85.53%) of HCV Ab positive patients. There were 3 males with HCVcAg levels in grey zone (3-11 fmol/L), and 8 cases with HCV Ab positive donors were also negative to HCVcAg (≤ 3 fmol/L). HCV RNA level was successfully determined in all cases of HCVcAg in positive and grey zone (68 cases, 100%) and 3 of 8 cases in which HCVcAg was negative (37.5%) (Table 2).
ROC curve analysis revealed cutoff of HCV Ab, HCVcAg and HCV RNA was 1.67 index, 2.82 fmol/L and 455 IU/mL respectively. HCVcAg has area under curve (AUC), sensitivity, specificity, positive and negative predictive values were 0.981, 97.14, 100, 100 and 99.76 respectively, with p<0.0001 when com-pared to values of HCV RNA test (Table 3).
Among cases with positive of both HCVcAg and HCV RNA, there was statistical significant link between HCVcAg and HCV RNA levels (r=0.759; p <0.001 - Figure 1).
Table (1): Demographic and virological markers in studied donors
Parameters |
Values |
Total donors No (%) |
4222 (100) |
Males / females: No % |
3837/385 90.88/9.12 |
Positive HCV-Ab No (%) |
76 (1.80) |
Males / females No (%) |
72/4 (94.74/5.26) |
Age years :mean±SD Range |
37.01±5.32 (26.0-50.0) |
HCV core Ag fmol/L : mean±SD Range |
473.78±539.89 (0.23 - 2072) |
HCV-RNA Log10 IU/mL : mean±SD Range |
6.12±6.30 (0.0 - 6.94) |
Table (2): Comparative results of HCV core Ag and HCV RNA in HCV-Ab positive sera
HCV
Parameters |
HCVAntibodies positive sample No (%) |
HCV Ag values (fmol/L) Mean (range) |
No of HCV RNA positive sample |
Positive (> 11 fmol/L) |
65 (85.53)
|
560.5 (17.0 - 2072.0) |
65 |
Gray zone (3 - 11 fmol/L) |
3 (3.94) |
6.28 (4.33-8.32) |
3 |
Negative (<3 fmol/L) |
8 (10.53)
|
1.74 (0.18-2.82) |
3 |
Table (3): ROC curve results of HCV-Ab, HCVcAg and HCV RNA at a cutoff 455 IU/mL
Test Parameters |
HCV Ab test |
HCVcAg test |
AUC |
0.939 |
0.981 |
Cut off |
1.67 |
2.82 |
Sensitivity |
81.43 |
97.14 |
Specificity |
100 |
100 |
PPV |
100 |
100 |
NPV |
98.48 |
99.76 |
P value |
0.0001 |
0.0001 |
AUC= Area under curve; PPV= positive predictive value; NPV= negative predictive value.
Figure (1): Correlation between HCV core Ag and HCV-RNA
DISCUSSION
Hepatitis C virus (HCV) has been reported to be on the decline over the past decade, although it remains a major public health concern in Saudi Arabia. In current study, blood samples from 4222 subjects (90.88% males and 9.12% females) were randomly collected, and analyzed. The results indicated that 76 (1.80%) cases were positive for anti-HCV antibody only (94.74% males and 5.26% females) with a mean age 37.01±5.32 years. However, in Saudi Arabia, the HCV prevalence in blood donors ranges from 0.4% to 1.9% (El-Beltagy et al., 2008; Abdo et al., 2012; Abdullah, 2013 and Alhetheel & El-Hazmi, 2014).
The prevalence of HCV infection in blood donors among American was 0.072% (Zou et al., 2009), in North Europeans 0.01% - 0.02% and in South Europeans was 1-1.5% (Khodabandehloo et al., 2013).
HCV RNA detection remains gold standard for the early diagnosis and confirmation of active HCV infection (Waldenström et al., 2013), but high costs, time consumption, requirement of sophisticated equipment, and skilled manpower of HCV RNA have turned it not to be frequently used in the developing countries of Africa, Asia and Latin America (Zhang et al., 2007). Therefore, during past decades, researchers have put enormous effort to develop HCVcAg, an otherwise economic and easy to perform assay, as a potential alternative to HCV RNA tests (Chakravarti et al., 2013).
Compared to PCR technique, HCVcAg assay is simple as HCV antibodies assay and can detect HCV infection only 1 day delay compared to the HCV RNA assay. HCVcAg tests have been introduced for monitoring of antiviral therapy as well as for diagnosis of HCV infection (Nguyen et al., 2016).
Among HCV-antibody positive speci-mens, 93.42% were positive by HCV RNA-PCR while 85.53% were positive by HCVcAg test, 3.94% was borderline (grey zone) and 10.53% were negative. In the present study, viral load was in the range of 700–4900 IU/mL in the three HCV RNA positive HCVcAg borderline subjects and in the range of 455–1500 IU/mL in HCV RNA positive/HCVcAg negative specimens.
The sample with the lowest serum level of HCV RNA (455 IU/mL), which was tested positive for HCVcAg (2.82 fmol/L) may be accepted as the lower limit of range for analytical sensitivity for HCVcAg assay, from our study. This correlated with the study performed by Hassan et al. (2014) who revealed that 3 fmol/L core antigen is equivalent to 263 IU/mL HCV RNA. Abd El-Reheem et al. (2016) demonstrated sensitivity in clinical specimen’s equivalent to 1200 IU/mL HCV RNA. Other studies suggesting it is around 7000 IU/mL (Zhang et al. 2007 and Abed Al-Gani, 2011). Furthermore, Feng et al. (2014) indicated that enzyme immunoassay tests for HCVcAg do not detect it when HCV RNA is below 15,000 IU/ml, which limits their use in clinical practice.
In this study, the sensitivity, specificity, PPV, NPV of the HCVcAg assay to detect HCV infection, compared to HCV RNA in studied donors were 97.14%, 100%, 100% and 99.76% respectively. Our results were higher than those reported by Park et al. (2010) (90.2%), and Feng et al. (2014) (95.2%). Similar specificity was reported by Morota et al. (2009) (99.98%), Miedouge et al. (2010) (99.2%), Ross et al. (2010) (100%)and Medici et al. (2011) (100%).
Koroglu et al. (2012) found that sensitivity, specificity and positive and negative predictive values were 96.9%, 100%, 100% and 99.1%, respectively. Kesli et al. (2011) found that sensitivity, specificity and positive and negative predictive values were 96.3%, 100%, 100% and 89.7%, respectively. In addition, Park et al. (2010) obtained similar results comparing HCV RNA with HCVcAg. Sensitivity, specificity and positive and negative predictive values were determined to be 90.2%, 100%, 100% and 86,4%, respectively.
The optimum cutoff of the HCVcAg assay in our study was 2.82 fmol/l (i.e. 0.06 pg/ml). This assay (Architect HCV core antigen assay) is therefore more sensitive than similar assays utilized in a study of Bucket et al. (2014) i.e. 3.44 fmol/l. In addition, the ROC curve analysis showed a closer sensitivity and specificity rates with HCV RNA results if HCVcAg is ≥2.82 fmol/L. This finding was close to the manufacturer's cut-off (3 fmol/L). However, we considered that the small difference might be due to the low number of negative patients.
In our study there was a statistical significant positive link between HCVcAg and HCV RNA levels. Numerous studies have explored the correlation between HCV RNA values and HCVcAg (Morota et al., 2009; Miedouge et al., 2010; Murayama et al., 2012; Waldenström et al., 2013; Bucket et al., 2014 and Tillmann, 2014).
This would indicate that detection of HCVcAg assay in serum or plasma is useful as an indirect marker of HCV replication due to the good correlation between HCVcAg and HCV RNA levels, as well as HCVcAg assay is highly sensitive compared to HCV RNA tests. Such studies explored the option to shorten the window of HCV seroconversion when HCVcAg would be used vs anti-HCV testing, and compared the performance of the HCVcAg to that of HCV RNA testing, and in common HCVcAg leads to earlier detection compared to anti-HCV.
However, since we conducted this study with anti-HCV antibody positive serum samples, we did not have any sample with a result like HCVcAg -reactive and anti-HCV antibody negative. So, we were not able to consider whether the early HCV infection without antibodies could be detected using the HCVcAg assay. But high specificity and the simplicity of HCVcAg, the rapid turnaround time of the results and its lower price suggest that it could be cost effectively applied in clinical practice.
CONCLUSION
The Architect HCVcAg assay poten-tially offers a good alternative to HCV RNA quantification. It is opera-tionally easier with low time-assay and low cost per assay, suggesting that it is likely to be established in the blood banks as a tool to aid in early diagnosis of HCV infection.
REFERENCES
1. Abd El-Reheem EM, Fouad M, Fath El-bab HKH and Abd El-Hmeed WM (2016): The utility of automated HCV core antigen assay as an alternative to PCR in chronic HCV Egyptian patients. J Mol Biomark Diagn., 7 (2): 275-79.
2. Abdo AA, Sanai FM and Al-Faleh FZ (2012): Epidemiology of viral hepatitis in Saudi Arabia: are we off the hook? Saudi J Gastroenterol., 18: 349-57.
3. Abdullah MS (2013): Prevalence of hepatitis B and C in donated blood from the Jazan region of Saudi Arabia. Malays J Med Sci., 20: 41-46.
4. Abed Al-Gani F (2011): Prevalence of HBV, HCV and HIV-1, 2 infections among blood donors in Prince Rashed Ben Al-Hassan Hospital in North Region of Jordan. Int J Biol Med Res., 2(4): 912 - 916.
5. Alhetheel A and El-Hazmi MM (2014): Hepatitis G virus in Saudi blood donors and chronic hepatitis B and C patients. J Infect Dev Ctries., 8(1):110-115.
6. Bucket CA, Ayse A, Selcuk K, Suleyman O and Emel SC (2014): Comparison of HCV core antigen and anti-HCV with HCV RNA results. African Health Sciences., 14 (4): 816-20.
7. Chakravarti A, Chauhan MS, Dogra G and Banerjee S (2013): Hepatitis C virus core antigen assay: can we think beyond convention in resource limited settings? Braz J Infect Dis., 17(3):369–74.
8. El Beltagy KE, Al Balawi IA, Maha A and Ziad AM (2008): Prevalence of hepatitis B virus markers among blood donors in a tertiary hospital in Tabuk, Northwestern Saudi Arabia. Int. J. Infect. Dis., 12:495-499.
9. Elbjeirami WM, Arsheed NM, Al-Jedani HM, Elnagdy N and Hazem M (2015): Prevalence and Trends of HBV, HCV, and HIV Serological and NAT Markers and Profiles in Saudi Blood Donors. J Blood Disord Transfus., 6 (3): 280-89.
10. Feng B, Yang R , Xie Q , Shang J, Kong F, Zhang HY, Rao H, Jin Q, Cong X, Liu Y, Kang Y and Wei L (2014): Hepatitis C virus core antigen, an earlier and stronger predictor on sustained virological response in patients with genotype 1 HCV infection. Gastroente-rology., 14:47.
11. Hassan HA, AbuTalib NA, Elsammak M, Maraqa A, Amr SS and Abdalhamid B (2014): HCV Core Antigen Testing versus HCV PCR Testing for Early Detection of HCV Infection. Egyptian Journal of Medical Microbiology., 23 (2): 67-74.
12. Kesli R, Polat H and Terzi Y (2011): Comparison of a newly developed automated and quantitative hepatitis C virus (HCV) core antigen test with the HCV RNA assay for clinical usefulness in confirming anti-HCV results. J Clin Microbiol., 49(12): 4089–93.
13. Khodabandehloo M, Roshani D and Sayehmiri K (2013): Prevalence and trend of hepatitis C virus infection among blood donors in Iran: A systematic review and meta-analysis. J Res Sci., 18 (8): 674-82.
14. Koroglu M, Ak S and Ak M (2012): Evaluation of diagnostic performance of new antigen-based enzyme immune assay for diagnosis of Hepatitis C virus (HCV) infections. Afr J Microbiol., 6(4): 809-12.
15. Mastro TD, Morrison CS and Hamilton CD (2016): Determining the Incidence of Hepatitis C Virus Infection in Populations: An Important Tool for Epidemic Control. I Infect Dis., 214 (3): 339-340.
16. Mederacke I, Wedemeyer H, Ciesek S, Steinmann E, Raupach R, Wursthorn K, Manns MP and Tillmann HL (2009): Performance and clinical utility of a novel fully automated quantitative HCV-core antigen assay. J Clin Virol., 46:210–215.
17. Medici MC, Furlini G and Rodella A (2011): Hepatitis C virus core antigen: Analytical performances, correlation with viremia and potential applications of a quantitative, automated immunoassay. J Clin Virol., 51:264-69.
18. Miedouge M, Saune K, Kamar N, Rieu M, Rostaing L and Izopet J (2010): Analytical evaluation of HCV core antigen and interest for HCV screening in haemodialysis patients. J Clin Virol., 48:18–21.
19. Morota K, Fujinami R and Kinukawa H (2009): A new sensitive and automated chemiluminescent microparticle immunoassay for quantitative determination of hepatitis C virus core antigen. J Virol Methods., 157:8-14.
20. Murayama A, Sugiyama N, Watashi K, Masaki T, Suzuki R, Aizaki H, Mizuochi T, Wakita T and Kato T (2012): Japanese reference panel of blood specimens for evaluation of hepatitis C virus RNA and core antigen quantitative assays. J Clin Microbiol., 50: 1943-49.
21. Nguyen LT, Gray E, O'Leary A, Carr M and De Gascun CF (2016): The Role of Hepatitis C Virus Core Antigen Testing in the Era of Direct Acting Antiviral Therapies: What We Can Learn from the Protease Inhibitors. PLoS ONE, 11(10): 1-16.
22. Park Y, Lee JH, Kim BS, Kim DY, Han KH and Kim HS (2010): New automated hepatitis C virus (HCV) core antigen assay as an alternative to real-time PCR for HCV RNA quantification. J Clin Microbiol., 48:2253–6.
23. Ross RS, Viazov S, Salloum S, Hilgard P, Gerken G and Roggendorf M (2010): Analytical performance characteristics and clinical utility of a novel assay for total hepatitis C virus core antigen quanti_cation. J Clin Microbiol., 48:1161-1168.
24. Tillmann HL (2014): Hepatitis C virus core antigen testing: Role in diagnosis, disease monitoring and treatment. World J Gastroenterol., 20(22): 6701-6706
25. Waldenström J, Konar J, Ekermo B, Norder H and Lagging M (2013): Neonatal transfusion-transmitted hepatitis C virus infection following a pre-seroconversion window-phase donation in Sweden. Scand J Infect Dis., 45: 796-99.
26. Zhang HQ, Li SB and Wang GH (2007): Detection of hepatitis C virus core antigen for early diagnosis of hepatitis C virus infection in plasma donor in China. World J Gastroenterol., 13:2738–42.
27. Zou S, Stramer SL, Notari EP, Kuhns MC, Krysztof D and Musavi F (2009): Current incidence and residual risk of hepatitis B infection among blood donors in the United States. Transfusion, 49(8):1609–1620.
إمکانیة إستخدام مستضد لب فیروس سی کبدیل لتفاعل البلمرة التسلسلی فی التشخیص المبکر لفیروس سی لدی المتبرعین بالدم
محمـد العراقی صالح - محمود سعودی- أمیمة سید محمـد*
قسم الباثولوجیا الإکلینیکیة - کلیة الطب - جامعة الأزهر
وقسم المیکروبیولوجی - کلیة الطب - جامعة عین شمس*
خلفیة البحث: یعتمد نقل الدم بطریقة آمنة علی المسح المناسب للعدوی المتنقلة خاصة فیروس سی الکبدی للمتبرعین بالدم. ویعتبر إختبار البلمرة التسلسلی لفیروس سی هو أهم الإختبارات فی تشخیص فیروس سی ولکن هناک صعوبة فی عمل هذا الإختبار وزیادة تکلفته المادیة و طول وقت إجرائه مقارنة بتحلیل مستضد لب فیروس سی.
الهدف من البحث: تقییم تحلیل مستضد لب فیروس سی کبدیل لتفاعل البلمرة التسلسلی فی الکشف المبکر عن فیروس سی فی المتبرعین بالدم.
المرضی و أدوات البحث: أجریت الدراسة الحالیة علی 4222 متبرع بالدم (3837 من الذکور و385 من الاناث) ببنک الدم الرئیسی - جامعة نجران - السعودیة العربیة فی الفترة من شهر مارس 2015 وحتی شهر یونیو 2016. وتم الکشف عن الفیروس الکبدی بی و سی و الزهری و فیروس الإیدز, وإستبعاد کل ما هو موجب تجاه الفیروس الکبدی بی والزهری و فیروس الإیدز, وتم عمل إختبار تفاعل البلمرة التسلسلی و تحلیل مستضد لب فیروس سی علی وحدات الدم موجبة مضادات فیروس سی و التی بلغت 76 وحدة دم : 72 من الذکور و 4 من الإناث.
النتائج : کان تحلیل مستضد لب فیروس سی إیجابی فی 65 حالة , وکان مستواه فی المساحة الرمادیة فی 3 حالات , و سلبی فی 8 حالات من إجمالی 76 حالة موجبة مضادات فیروس سی. بینما کانت نتائج تحلیل تفاعل البلمرة التسلسلی إیجابی فی 71 حالة بنسبة 93.42% , وإیجابی فی ثلاث من ثمان حالات موجبة مضادات فیروس سی وسالبة مستضد لب فیروس سی
الإستنتاج: إرتفاع نسبة حساسیة وخصوصیة تحلیل مستضد لب فیروس سی بنسب قریبة من تفاعل البلمرة التسلسلی , مع قصر مدة إجراء التحلیل و قلة تکلفته المادیة تجعل إمکانیة لإستخدام تحلیل مستضد لب فیروس سی کبدیل لتفاعل البلمرة التسلسلی فی الکشف المبکر عن فیروس سی فی المتبرعین بالدم