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Article

Prevalence and Trends in Hepatitis B & C Virus among Blood Donors in Pakistan: A Regional Transfusion Center Study

by
Tehreem Zorob
1,2,†,
Muhammad Awais Farooqi
1,3,†,
Ali Ahsan
4,
Abdullah Zaki
5,
Muhammad Ali Rathore
1,* and
Hafiz Muhammad Umer Farooqi
6,*
1
Department of Virology, Armed Forces Institute of Transfusion, National University of Medical Sciences, Rawalpindi 46000, Pakistan
2
Department of Life Sciences, Abasyn University Islamabad Campus, Islamabad 44000, Pakistan
3
Department of Mechatronics Engineering, Jeju National University, Jeju-si 63243, Republic of Korea
4
Graduate School of Science, Osaka Metropolitan University, Osaka 558-0022, Japan
5
Department of Neurology, Shifa International Hospital, Sector H-8, Islamabad 44000, Pakistan
6
Board of Governors Regenerative Medicine Institute, Cedars-Sinai Medical Center, Los Angeles, CA 90048, USA
*
Authors to whom correspondence should be addressed.
These authors contributed equally to this work.
Livers 2023, 3(2), 271-281; https://doi.org/10.3390/livers3020018
Submission received: 20 February 2023 / Revised: 26 April 2023 / Accepted: 11 May 2023 / Published: 17 May 2023

Abstract

:
Around 118.5 million blood donations are collected annually to save precious lives. The donated blood may also be associated with blood-borne infections. With around 247 million population, Pakistan is an endemic country for viral hepatitis, and there is a high risk of having asymptomatic blood donors among healthy donors. Viral hepatitis is 2.5% prevalent in the general population, and blood donation and its screening have become grave health concerns for Pakistani health authorities. Asymptomatic viral hepatitis needs screening to rule out subliminally diseased individuals, as recommended by the World Health Organization. Knowing the prevalence of the transfusion transmissible infectious (TTIs) agents in healthy blood donors helps assess the disease burden in any population, boosts treatment rates, and precludes dreaded complications in the affected people. The objective of the current study was to determine the prevalence and trends of significant TTIs among blood donors visiting the Armed Forces Institute of Transfusion (AFIT), Rawalpindi, Pakistan. A total of 15,405 blood donors were screened for HBV, HCV, HIV, malaria, and syphilis during this cross-sectional descriptive study. Most donors had an O-positive blood group; AB-negative donors were only 0.7%. Out of the study population, we reported 1.06% HBV, 0.54% HCV, 0.19% HIV, and 0.31% syphilis-positive asymptomatic blood donors. However, no blood donor was found positive for malaria. The Punjab province was reported as the most burdened for TTIs, and youngsters aged 18–27 years were mainly positive, indicating the need to conduct national-level awareness campaigns about TTIs. The stakeholders need to strengthen the blood collection guidelines, and effective performance should be strictly monitored through internal and external audits considering the aim of reaching non-infectious blood products.

1. Introduction

Blood transfusion plays a pivotal role in the healthcare system by improving the patient’s life, is considered a lifesaving intervention, and supports countless patients globally. According to World Health Organization (WHO), 118.5 million blood donations are collected worldwide annually, and around two-fifth of these are made in high-income countries [1]. Pakistan, a developing nation, faces healthcare system challenges due to a lack of resources, including being the globally second highest prevalence of Hepatitis B Virus (HBV) infection in the general population, succeeded by Egypt, and being the 5th most burdened country with Tuberculosis. Out of the world’s 8 billion population, around 296 million people are infected with HBV, followed by 0.82 million deaths yearly [2]. A recent study reported that 9 million people out of the 232 million population of Pakistan harbor the HBV infection [3]. Blood donation saves lives and, at the same time, is a risk factor associated with Transfusion transmissible infections (TTIs). The major pathogens involved in TTIs are HBV, Hepatitis C virus (HCV), Human Immunodeficiency Virus (HIV), syphilis-associated Treponema pallidum, and Plasmodium species-associated malaria. The transfusion of infected blood or blood components increases the probability of patients’ mortality and morbidity; thus, measuring the risk of TTIs linked with the blood transfusion is prudent.
Viral hepatitis is a global public health concern and is endemic in developing countries and a significant cause of morbidity and mortality in Pakistan [4]. It is caused by hepatitis virus subfamilies, including Hepatitis A, B, C, D, E, and G. The HBV and HCV belong to the genus of Orthohepadnavirus and Hepacvirus, respectively, and are involved in severe liver pathologies leading to cirrhosis and hepatocellular carcinoma. HBV is a silent killer that persists in the body as a carrier. Blood-transfusion-related HBV infection remains a critical concern in transfusion medicine. HBV, HCV, and HIV spread when blood, semen, or other body fluids from an infected person enter the body of someone who is not infected. The etiologies also include using unautoclaved instruments during surgical procedures, drug abuse, unprotected sex, unregulated piercing and tattooing with non-sterile instruments, and, sometimes, the vertical transmission of infections from the mother to the newborn [5]. In developing countries, unsafe blood products are still a significant problem due to the transmission of the pathogenic virus, posing enormous public health concerns [6,7]. According to the U.S. Centers for Disease Control and Prevention, approximately 3000 people in the U.S. and more than 600,000 people worldwide die from HBV-related liver disease yearly. The statistics by WHO reported at the end of 2021 that approximately 38.4 million of the world’s population were infected with HIV [8], 2–3% of the global population harbor HCV [9], around 3.2% people were reported syphilis positive in 2019 [10], and 247 million malaria cases were reported across the globe [11].
The clinical picture of blood-borne infections is highly variable. The infected individuals can be asymptomatic or present with typical signs of disease, including jaundice, dark urine, hepatomegaly, anorexia, malaise, fever, nausea, abdominal pain, and vomiting [12,13,14]. Pakistan is an endemic country for TTIs; thus, there is a high risk of having asymptomatic donors among healthy individuals. These TTIs need strict screening and compliance with safe blood transfusion practices to rule out subliminally diseased individuals. The Ministry of National Health Services, Regulations and Coordination (MoNHSR&C), Government of Pakistan has issued Safe Blood Transfusion Guidelines (SBTG) for screening five cardinal TTIs-associated pathogens before proceeding with the blood transfusion [15]. Knowing the prevalence proportion of the viral markers associated with blood donation can help to assess the disease burden in any population. Preventive measures can be taken, and policymakers and stakeholders will help allocate the public-health-related budget in the endemic areas accordingly. Awareness seminars and volunteer camps can be accordingly planned to prevent and limit blood-transfusion-related infections spread in society. This study aimed to identify the incidence rate of TTIs-associated pathogens in healthy donors visiting the Armed Forces Institute of Transfusion (AFIT), Rawalpindi, Pakistan. Concerning the objective, the study was conducted to determine the prevalence of viral markers in healthy blood donors.

2. Materials and Methods

2.1. Study Design

The descriptive cross-sectional, single-centered study was conducted from 1 July 2019 to 31 December 2019. A total of 15,405 samples of blood donors were screened during the study period using a convenient sampling technique.

2.2. Settings and Population

The study was conducted at the AFIT, a facility attached to Pakistan’s primer reference laboratory, Armed Forces Institute of Pathology (AFIP), Rawalpindi, Pakistan [16]. Rawalpindi is a metropolitan city of the province of Punjab; it is the fourth largest city in Pakistan, with an area of 479 km2 and a population of nearly 21 million people. Rawalpindi city is situated just adjacent to Islamabad’s capital territory, and both cities are called twin cities. The study population belonged to all the provinces of Pakistan residing in Rawalpindi, Pakistan.

2.3. Sample Collection and Processing

The donor’s blood was drawn in two blood collection vacutainers. The ethylene-diamine tetra-acetic acid (EDTA) anticoagulant containing vacutainer was used to analyze the donors’ hemoglobin, hematocrit, platelet levels, and blood groups. The other vacutainer containing no anticoagulant was used to obtain serum to screen HBV, HCV, HIV, T. pallidum, and Plasmodium spp. The selection criteria included only healthy blood donors who visited the health center and fulfilled the donor selection criteria according to the WHO and SBTG guidelines [17].

2.4. Screening of Samples

The donor’s serum was quantified through chemiluminescence microplate immunoassay (CMIA) using the ABBOTT ARCHITECT i2000SR system (Sligo, Ireland). The concentrations of the analytes were determined using the ARCHITECT calibration curve. The sample was considered reactive if the sample’s concentration was >0.05 IU/mL. The software protocols for ARCHITECT HbsAg, HCV, HIV, malaria, and syphilis files were installed in the computer to run the instrument; frozen samples were thoroughly mixed after thawing. The reagent kit for the test assay was mixed around 30 times to resuspend microparticles. The discard cap and bag septum were removed and snapped onto the top of the bottle. The volume of reagent required for one test was around 150 μL and 25 μL of the sample. The recipients’ platelet levels, hemoglobin concentration, and hematocrit were measured using a Mindray BC-6200 (Nanshan, Shenzhen 518057, China) 5 parts differential hematology analyzer. The device could process 110 samples in 60 min. Hematocrit was the percentage by volume of red cells in the blood.

2.5. Ethical Approval

The Institutional review board’s (IRB) ethical approval (approval number AFIT-ERC-19-047) was taken before the sampling process. It was made sure that the participants’ information remained confidential and inaccessible to outsiders except for the research team. The data were analyzed and aligned using the software Statistical Package for Social Sciences (SPSS) v. 23.0, tables were drawn using Microsoft Excel 2019, and graphs were prepared using GraphPad Prism v.9.

2.6. Inclusion Criteria

The study included all recipients aged over 19 and under 60, with good physical health conditions and hemoglobin (Hb) levels no less than 12.5 g/dL. Vital signs of donors were noted, confirming the donors were healthy with systolic pressure between the range of 65–90 mmHg and systolic pressure between 100–120 mmHg, with few outliers depending upon the recipient’s clinical condition.

2.7. Exclusion Criteria

Persons having a donation gap of <3 months, drug abusers, men younger than 18, and sex workers were excluded from the study.

3. Results

3.1. Demographics of the Study Population

In total, 15,405 blood donors were screened for HBV, HCV, HIV, syphilis, and malaria during the study period. All the donors recorded during the current study were male, and no female donor was reported during the study period. The demographic distribution of the donors showed that the maximum number of donors (44%) belonged to the age group 18 to 27 (n = 6704). The frequency and percentage for the age group 28–37 was 36% (n = 5482), 38 to 47 was 14% (n = 2209), 48–57 was 5% (n = 724), and the least number of donors were reported between the age group 58 to 67 was 2% n = 286). The province-wide distribution of donors showed that the maximum number of donors belonged to Punjab 97.7% (n = 14,879), followed by Khyber Pakhtunkhwa (KPK) 3% (n = 495), and less than 1% from Azad Jammu Kashmir (AJK), Balochistan, and Gilgit Baltistan (GB); however, no patient was registered from Sindh. The hematological parameters of the donors showed that all the donors fell in the healthy donors’ category, indicating a healthy local population. The maximum number of donors had a hemoglobin value of 15 g/dL (n = 6732, 44%), followed by 16/dL 29% (n = 4419), 14 g/dL 23% (n = 3613), and the minimum reported value was 13 g/dL 4% (n = 641). The percentage of red cells by volume in the donors indicated that the maximum number of patients fell in the 45% hematocrit range (42%, n = 6437). The frequency of hematocrit values for the rest of the donors was 41% to 49%. The platelet count assessment showed that all the study participants had a standard range of platelet levels, with a maximum of participants 86% (n = 13,238) having 251–350 × 109 platelets per L. According to the province-wide distribution, the patients of Punjab province contributed the maximum to the study; 97% (n = 14,879) of the donors belonged to Punjab, followed by KPK 3% (n = 495), Balochistan was 0.10% (15), and 0.1% (n = 16) both for GB and AJK. However, no donor was registered from the Sindh province of Pakistan. The donors’ frequencies and demographics are summarized in Table 1.

3.2. Blood Group Statistics

The forward blood group profiling using the tile method showed that 91.57% (14,107) of donors belonged to the Rhesus factor D (RhD) positive blood group, and 8.43% (1298) were the RhD, negative blood group. In the case of RhD-positive blood group donors, a major proportion was the O-positive blood group, 32.96% (n = 5077); followed by the B-positive blood group, 34.72% (n = 5349); and A-positive blood group, 16.46% (n = 2535). A minor percentage was witnessed in the case of AB-positive blood group donors, 7.44% (n = 1146). In the case of RhD-negative donors, the frequency and percentage of the donors for B-negative, O-negative, A-negative, and AB-negative donors was 3.25% (500), 2.99% (n = 461), 1.49% (n = 229), and 0.70% (n = 108), respectively (Table 2).

3.3. Disease Burden

The prevalence of the Hepatitis B surface-antigen-test-positive patients during the study period was 1.06% (n = 164). The age-wise distribution of the HBV-positive patients showed that half the blood donors were 18–27 years old. The HCV-positive patients contributed 0.54% (n = 83) burden of the study, and a varying range of patients was reported for 18–27 years (n = 37), 28–37 years (n = 28), and the rest of the patients belonged to age groups >37. The trend for HIV screening was 0.19% (n = 30), where, surprisingly, young adults aged 18–27 years showed a 3/4th burden of total HIV positivity. The syphilis screening test showed that 0.31% (n = 48) were positive for the Treponema pallidum test, and around half the burden of patients belonged to middle-aged young people, i.e., 28–37 years. The data for screening results and their association with age groups is shown in Figure 1.
Concerning the positivity related to provincial categorization, the maximum positive cases for HBsAg were reported from Punjab at 1.02% (n = 157), 0.5% (n = 81) for HCV, 0.17% (n = 26) for HIV, and 0.29% (n = 46) for syphilis. Succeeded by Punjab, KPK remained 2nd in trend, and HBsAg positive was 0.05% (n = 7), HCV positive was 0.01% (n = 3), HIV positive was 0.02 (n = 2), and syphilis positive was 0.01% (n = 2). The trend for the province-wide distribution of patients with age and screening tests is given in Figure 2.
The chemiluminescence microplate immunoassay for the patients showed that the population had a high burden of Hepatitis B surface antigen in their blood in around one-fifth of the study. The antigen quantification showed that the antigen burden in 29.3% of patients ranged between a quarter proportion (24.4%) of patients that went between 3001 and 4500, 21.3% fell within the 1501–3000 range, around two fifths of the proportion (20.7%) were between 4501 and 6000, and the low sensitive zone, i.e., grey-zone-ranged patients, were only 4.3%, with the sample to the cutoff ratio between 0.8 and 1. The grey zone of the quantitative test was an area of values where the discriminatory performance was ‘insufficient’, The value in the grey zone did not allow the target disease to be scored as either present or absent. Grey zone values for the HBsAg were generally considered indeterminate, as they did not necessarily indicate a positive or negative result for HBV infection. Our study defined the grey zone as HBsAg values between 0.05 IU/mL and 0.49 IU/mL. We performed repeat testing of the same sample using a similar assay to determine the accuracy of the initial test results in the grey zone. We also tested a second sample collected from the same participant at a later point to confirm the initial results. If the results of both tests were positive or negative, we classified the participant accordingly [18] (Table 3).

4. Discussion

Around 118.5 million people donate blood annually for charity, emergencies, operations, and maternity cases. Blood donation is a noble cause of saving one’s life. For instance, in the case of roadside accidents with massive bleeding, screening individuals with TTIs gives an insight into the burden and magnitude of certain diseases in the country [19]. Hepatitis B and Hepatitis C infections are characterized by short-term infection within the first six months after someone is infected with these pathogens. The severity can range from mild illness with few or no symptoms to a severe condition requiring immediate hospitalization and intensive care [20,21]. Some adults can get rid of the virus without treatment, and those that can clear the virus become immune and do not develop clinical symptoms and infection with subsequent exposure. The medications for HBV and HCV are routinely available in Pakistan’s public and private sectors. The government of Pakistan provides free-of-cost antiviral medications for HBV and HCV in public sector hospitals and clinics. These medications are included in the essential medicines list and are distributed through the National Program for Hepatitis Control and Prevention (NPHCP). The NPHCP aims to provide prevention, diagnosis, and treatment services for HBV and HCV at the national level and has set up dedicated treatment centers nationwide to facilitate patient access to care. In addition, private healthcare facilities in Pakistan also offer medications for HBV and HCV. However, the cost of these medications may vary depending on the brand and the facility’s location. It is worth noting that access to treatment for HBV and HCV remains a challenge in Pakistan despite the availability of medicines. Factors such as limited healthcare infrastructure, low awareness about disease screening and their treatment, and stigma associated with these infections contribute to inadequate treatment uptake [22]. In addition to this, there could be several reasons for the higher prevalence of these infections in the younger population. One possible explanation is that young individuals may engage in more high-risk behaviors, such as unprotected sex or injection-based narcotics or drug abuse, which increase their risk of acquiring such infections. Additionally, younger individuals may be less likely to have been vaccinated against HBV or previously exposed to the virus, which could also contribute to the higher prevalence observed in this age group.
In the current study, the overall seroprevalence of HBV in the subjects was 1.06%. While a previous study by Niazi et al., 2016 [23] at the same institution reported a 1.48% prevalence of HBV in blood donors. Similarly, another study by Butt et al., 2017 [24] reported a 1.57% burden proportion of HBV in Rawalpindi, and the report of Abdullah et al., 2019 [25] suggested a 1.5% HBV burden in Lahore city of Punjab. In the southern part of Punjab, a study by Akhter et al., 2018 and Billah et al., 2018 reported 1.5% and 1% HBV burdens in blood donors visiting health facilities, respectively [26,27]. These results were consistent with the current research that the overall burden was less than two percent in major cities in Pakistan. Concerning the country-wise burden of HBV, Sajjadi et al., 2018 reported 0.13% in Iran [28], Hussein et al., 2017 reported 0.78% in Iraq [29], Alzahrani et al., 2019 reported 3.24% in Eastern Saudi Arabia [30], Ezeonu et al., 2019 [31] and Shah et al., 2018 reported 0.7% in Nepal [32], Bartonjo reported 6.8% in Kenya, Bartonjo et al., 2019 reported 6.8% in Kenya [33], Islam et al., 2016 reported 5.4% in Afghanistan [34], Baptiste et al., 2018 reported 3.80% in Haiti [35], and Wang et al., 2019 reported 6.89% HBV-positive patients in China [36].
The current study reported that most HBV-infected patients, 70% (n = 115), belonged to younger age groups, i.e., 18 to 30 years of age, which showed the state that authorities need to be more vigilant about to work against the spread of the Hepatitis infection. Another study [23] reported a higher prevalence of HBV infection in age groups of 31 to 45 years of age in Rawalpindi than in the current study. Another survey by Billah et al., 2018 in Multan reported a prevalence of HBV-infected donors aged 18–30 [27]. The report by Naveed et al., 2016 in Multan City also reported the detection of HBV infection in the age groups 31–45 years [37]. The current study’s findings were also consistent with the results cited previously in the literature from Nigeria [31]. The stakeholders and policymakers should seriously take up measures to combat against spread of all blood-borne pathogens to create a healthy society [38]. Additionally, if the prevalence of such cases increases, the community would be short of blood donors in medical emergencies such as natural disasters, terrorism-related events, roadside accidents, or maternity case emergencies.
The results depicted in our study are an appreciating outcome of the current implementing policies by the regional Punjab Blood Transfusion Authority (PBTA). Still, it is also evident that the progress toward achieving specific results is slow or sluggish. Another reason for the reduction in HBV, HCV, and HIV proportion that might be associated with the Extended Program on Immunization (EPI) by MoNHSR&C and the utilization of retroviral therapies [39]. An enormous load of the patient population and disease-free state policies are a severe challenge to healthcare departments. The upsurge in disease burden is an intense concern for the patients, physicians, policymakers, and society who wish to see a safe blood supply.
The global proportion of HIV is increasing enormously; the recent study by Marfani et al., 2022 reported that the National Aids Control Program has 24,331 registered cases of HIV-positive patients, and they estimated the number of infected persons is around 165,000 in total [40]. The current study reported 30 HIV-positive patients belonging to very young age groups, indicating that the preventive measures taken by the state still need to be improved. With the increase in drug addiction among youngsters, the non-utilization of precautions before intercourse with sex workers and the use of contaminated and reused surgical instruments might be a leading cause of this grave concern. The situation with the case of syphilis is almost similar to other TTIs; however, the number is still low compared to the TTIs mentioned above.
Immunocompetent adults recover from HBV after 4–8 months; however, for the rest of the population, the need of the hour is to ensure low-cost treatment and follow-up check-ups with the addition of volunteer camps, government, and adoption. They are considering the regional differences in disease prevalence to support the periodic update of the majority in the country. One of the critical limitations of this study is the single-gender participation because the highly predominant male population might cause biases compared to the contrasting gender, i.e., females [41,42]. The lack of female donors in the study population may limit our findings’ generalizability to Pakistan. However, the current study aimed to assess the prevalence of TTIs among healthy donors in the study area and not to evaluate gender-specific donation rates in Pakistan. Moreover, the study is based on single regional center data, and the results cannot broadly represent the general population of Pakistan. At the same time, the females should also be encouraged to donate blood, which would not only meet the growing demand of short blood supply in healthcare departments but also the screening of those females for TTIs would give an insight into the burden of blood-borne diseases in women as well. Using a single-centered institution, we conducted the study to assess the nationwide TTIs’ burden. More studies should be conducted in the general population and areas where the disease is endemic, and treatment facilities and guidelines should be given accordingly.

5. Conclusions

A high percentage of healthy donors affected with HBV, HCV, and HIV were witnessed in the tertiary care healthcare center, with the prevalence of people from the youngest age groups. The study showed a decline in the HBV burden compared to the previous studies, indicating a better but slow implementation of the health policies. The stakeholders need to strengthen the guidelines, and effective performance should be strictly monitored through internal and external audits, considering the aim of reaching a disease-free society. The disease burden was found more in the Punjab province in the young age group, indicating the need to conduct awareness seminars and volunteer camps for youngsters. Effective screening should be made mandatory, thus achieving zero transmission risk.

Author Contributions

Conceptualization, H.M.U.F. and M.A.R.; methodology, T.Z. and M.A.F.; software, A.A.; validation, M.A.F. and A.Z.; formal analysis, T.Z.; investigation, M.A.F.; resources, M.A.R.; data curation, M.A.F.; writing—original draft preparation, T.Z. and M.A.F.; writing—review and editing, A.Z.; visualization, A.A.; supervision, H.M.U.F. and M.A.R. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

The study was conducted following the Armed Forces Institute of Transfusion Medicine’s declaration and approved by the Institutional Review Board letter AFIT-ERC-19-047.

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

All the supporting data concerning the study are available and can be obtained from the corresponding authors upon reasonable request.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Age versus pathogen analysis.
Figure 1. Age versus pathogen analysis.
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Figure 2. The burden of TTI diseases.
Figure 2. The burden of TTI diseases.
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Table 1. Demographics of the study population.
Table 1. Demographics of the study population.
Frequency (n)Percentage (%)
Age Groups (Years)
18–27670444
28–37548236
38–47220914
48–577245
58–672862
Gender
Male15,405100
Female00
Ethnicity
Punjab14,87997
KPK4953
Balochistan150.10
Gilgit Baltistan80.05
Azad Jammu Kashmir80.05
Hemoglobin Levels (g/dL)
12.5 to 13.996414
14 to 14.99361323
15 to 15.99673244
16 to 16.99441929
Hematocrit (%)
41 to 41.991831
42 to 42.9911568
43 to 43.997755
44 to 44.9912218
45 to 45.99643742
48 to 48.994753
49 to 49.991921
Platelets (109 platelets per L)
149–250214014
251–35013,23886
351–450270.1
HBsAg
Reactive1641
Non-Reactive15,24199
HCV
Reactive831
Non-Reactive15,32299
HIV
Reactive300
Non-Reactive15,375100
Malaria
Non-Reactive15,405100
Syphilis
Reactive480
Non-Reactive15,357100
Table 2. Distribution of ABO and RhD blood grouping.
Table 2. Distribution of ABO and RhD blood grouping.
Rhesus Factor-D (RhD)
Blood GroupPositive (n)Percentage (%)Negative (n)Percentage (%)Total (n)Percentage (%)
ABOA253516.462291.49276417.94
B534934.725003.25584937.97
AB11467.441080.7012548.14
O507732.964612.99553835.95
Total14,10791.5712988.4315,405100.00
Table 3. Serum to cut off value for HBV.
Table 3. Serum to cut off value for HBV.
ParameterFrequencyPercentage (%)
Grey Zone 0.8–174.30
>1–15004829.30
1501–30003521.30
3001–45004024.40
4501–60003420.70%
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MDPI and ACS Style

Zorob, T.; Farooqi, M.A.; Ahsan, A.; Zaki, A.; Rathore, M.A.; Farooqi, H.M.U. Prevalence and Trends in Hepatitis B & C Virus among Blood Donors in Pakistan: A Regional Transfusion Center Study. Livers 2023, 3, 271-281. https://doi.org/10.3390/livers3020018

AMA Style

Zorob T, Farooqi MA, Ahsan A, Zaki A, Rathore MA, Farooqi HMU. Prevalence and Trends in Hepatitis B & C Virus among Blood Donors in Pakistan: A Regional Transfusion Center Study. Livers. 2023; 3(2):271-281. https://doi.org/10.3390/livers3020018

Chicago/Turabian Style

Zorob, Tehreem, Muhammad Awais Farooqi, Ali Ahsan, Abdullah Zaki, Muhammad Ali Rathore, and Hafiz Muhammad Umer Farooqi. 2023. "Prevalence and Trends in Hepatitis B & C Virus among Blood Donors in Pakistan: A Regional Transfusion Center Study" Livers 3, no. 2: 271-281. https://doi.org/10.3390/livers3020018

APA Style

Zorob, T., Farooqi, M. A., Ahsan, A., Zaki, A., Rathore, M. A., & Farooqi, H. M. U. (2023). Prevalence and Trends in Hepatitis B & C Virus among Blood Donors in Pakistan: A Regional Transfusion Center Study. Livers, 3(2), 271-281. https://doi.org/10.3390/livers3020018

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