Abstract
HIV infection has been a global public health threat and overall reported ~ 40 million deaths. Acquired immunodeficiency syndrome (AIDS) is attributed to the retroviruses (HIV-1/2), disseminated through various body fluids. The temporal progression of AIDS is in context to the rate of HIV-1 infection, which is twice as protracted in HIV-2 transmission. Q-PCR is the only available method that requires a well-developed lab infrastructure and trained personnel. Micro-PCR, a portable Q-PCR device, was developed by Bigtec Labs, Bangalore, India. It is simple, accurate, fast, and operationalised in remote places where diagnostic services are inaccessible in developing countries. This novel micro-PCR determines HIV-1 and HIV-2 viral load using a TruePrep™ extractor device for RNA isolation. Five ml blood samples were collected at the blood collection centre at AIIMS, New Delhi, India. Samples were screened for serology, and a comparison of HIV-1/2 RNA was done between qPCR and micro-PCR in the samples. The micro-PCR assay of HIV-RNA has compared well with those from real-time PCR (r = 0.99, i < 0.002). Micro-PCR has good inter and intra-assay reproducibility over a wide dynamic range (1.0 × 102–1.0 × 108 IU/ml). The linear dynamic range was 102–108 IU/ml. The clinical and analytical specificity of the assay was comparable, i.e., 100%. Intra-assay and inter-assay coefficients of variation ranged from 1.17% to 3.15% and from 0.02% to 0.46%, respectively. Moreover, due to the robust, simple, and empirical method, the Probit analysis has also been done for qPCR LODs to avoid uncertainties in target recoveries. The micro-PCR is reliable, accurate, and reproducible for early detection of HIV-1 and HIV-2 viral loads simultaneously. Thus, it can easily be used in the field and in remote places where quantification of both HIV-1/2 is not reachable.
Similar content being viewed by others
Introduction
Human immunodeficiency virus (HIV) remains a substantial public health concern, with more than 39 million people living with HIV and, as of now, no cure for HIV, including opportunistic infections globally. It targets the body's white blood cells, weakening the immune system1. Around 6,30,000 deaths have been reported due to HIV-related causes, and 1.3 million people have acquired HIV in 2022. HIV-1 and HIV-2 are significant challenges in countries confined to regions of West Africa, India, Western Europe, Brazil, and many other regions2,3,4. When compared to HIV-1 infections, HIV-2 infections proceed at a slower rate, affecting 20–30% of infected individuals5. This shows that a lesser proportion of people infected with HIV-2 experience faster disease progression than those infected with HIV-1. Being left untreated with HIV-2 can lead to a higher risk of HIV transmission, higher cost of medical management, and increased mortality.
Moreover, the frequent cross-resistance and incomplete information about the resistance pathways limit the treatment options for HIV-1 and HIV-2 infections. The discovery and global roll-out of rapid diagnostics and effective antiretroviral therapies are being considered to reduce mortality and morbidity in groups of individuals requiring lifelong viral suppressive therapy. In Asia, 95% of HIV-2 infected cases come from are reported in India6. The prevalence of HIV-2 in India varies regionally, ranging between 2 and 33% of all HIV infections. These reports confirm infection serologically6,7. The frequency of HIV-2 in blood donors was reported at 2.8% (1.3% HIV-2 and 1.5% HIV-1/2 dual infection) of all HIV diagnoses at a tertiary referral hospital in southern India1. RNA testing is the approved diagnostic method for HIV screening of HIV-1/HIV-2 Ab combo assay in the sample. However, the difference between HIV-1/HIV-2 infection according to CDC guidelines still needs to be resolved. Therefore, for HIV prevention, treatment, and early care of HIV infection, urgently needs to assess the HIV-1 and HIV-2 detection in blood samples. Quantitative nucleic acid detection assays are primarily based on real-time PCR and are applicable for detecting molecular pathogens in diagnostics. They have developed as a crucial and valuable application, resulting in substantial advances in molecular diagnostics. Quantitative nucleic acid detection assays have become an essential and practical application of real-time PCR techniques, resulting in dramatic advances in molecular diagnostics8,9. However, no precise diagnostic assay has yet been approved by CE marked or the US FDA for detecting HIV-2 viral RNA.
However, most laboratories have developed the protocol for detecting HIV-2 RNA and are still sending the samples to national referral laboratories to confirm HIV reports as per the WHO consolidated guidelines10,11,12. Moreover, HIV RNA detection in plasma has enabled a new understanding and revolutionised the clinical setup of HIV-infected patients. Various HIV detection methods have been commercially developed and validated clinically13,14. Moreover, in-house methods for HIV-2 quantification by real-time PCR have been developed by the University of Washington and validated according to the College of American Pathology (CAP)15. Similarly, the public health agency of Canada has also developed HIV-2 viral quantification in digital droplet PCR (ddPCR) and validation done under the CAP regulations15. HIV-2 RNA kits are commercially available, such as Primer Design Limited, Southampton, UK, and Biocentric Bandel, France; they have been developed for research purposes only16,17. Unfortunately, due to the cost and technical constraints, patients living in countries with limited resources have not yet benefitted from molecular diagnostic tests18. They are restricted to centralised reference laboratories only. They have well-developed infrastructures and trained staff to perform real-time PCR for monitoring HIV-1/2 viral loads. Recently, Bigtec Labs, Bangalore, has developed a portable micro-PCR device, CHIP-based technology for detecting HIV-1 and HIV-2. The details of the processing steps are shown in Fig. 1. The significant key features of micro-PCR are rapid amplification, high sensitivity, and accurate quantification of HIV viral loads. The Micro-PCR system eliminates various issues related to HIV detection and monitoring in resource constrained situations by providing mobility, rapid results, less sample requirements, power efficiency, multiplexing capabilities, cost-effectiveness, and ease of use. This article describes a concise methodology for detecting HIV-1/2 viral load in patients utilising Micro-PCR technology and a statistical correlation with a previously established real-time PCR method. Therefore, for HIV prevention, treatment, and early care of HIV infection, urgently needs to assess the HIV-1 and HIV-2 quantification in blood samples.
Methods
Sample recruitment and collection
Three hundred subjects were screened from the Department of Medicine and HIV clinic AIIMS, New Delhi. Blood sampling was done from the Antiretroviral Therapy (ART) counters of the central collection facility, Department of Laboratory Medicine, AIIMS, New Delhi, for biochemical, serological and molecular tests. The AIIMS ethics committee approved the study, and informed consent was obtained from all the recruited patients. The methods employed in this study were conducted in accordance with the relevant guidelines and regulations as per the Declaration of Helsinki. EDTA and plain vials were used to collect 5.0 ml of blood samples, which were then centrifuged to separate the serum and plasma for processing. These samples were stored at − 80 °C till further processing steps. All subjects were screened for serology (anti-HCV antibody, IgM antiHBc, anti-HEV, HBsAg and HIV-1 &-2) and LFT (ALT, AST, Bilirubin). Serology of IgM antiHBc, anti-HEV and HBsAg was done using a commercially available ELISA kit (Bio-Rad Monalisa). HIV serology was done using the 4th generation ELISA kit (Genedia HIV Ag-Ab). In case the HIV serology is positive in patients, then patients were called for counselling and referred to the ART clinic, Department of Medicine, AIIMS, New Delhi, for further management of the patients. The case–control study involves 110 subjects divided into two groups: (I) HIV seropositive subjects (51 patients) and (II) Healthy subjects (59 patients). The LFT was done in the Department of Laboratory Medicine AIIMS, New Delhi. Out of 51 seropositive subjects, 26 for HIV-1 and 25 for HIV-2 were processed for further study.
RNA isolation
A total of 110 naive patients were included in the study by appropriate serological tests. The RNA from the patient sample is first extracted using TruePrep™ AUTO/AUTO v2 Universal cartridge-based sample prep device and TruePrep™ AUTO/AUTO v2 Universal cartridge-based sample prep kit according to the manufacturer’s protocol as shown in Fig. 2a, b. TruePrep™ uses the sample with a pretreatment reagent to automate the process of RNA isolation by lysing to the sample in the sample chamber, binding RNA to a solid support in a matrix chamber, and washing off the unwanted components followed by the elution of RNA from the solid support in the elution chamber. The yield of RNA concentration is obtained in the sample. The concentration of RNA was compared with the RNA obtained from the Qiagen isolation kit (Qiagen, Gmbh, Germany) by nanodrop spectrophotometer (Thermo Scientific, US).
Real-timePCR
After the elution of RNA, the Truenat™ HIV-1/2 chip is placed on the real-time micro-PCR Analyzer chip tray, as shown in Fig. 2c. Six µL of the extracted RNA is dispensed into the microtube containing RT-PCR master mix reagents and kept for incubation at 60 s. Six µl of this solution is dispensed into the reaction well of the Truenat™ HIV-1/2 chip, wherein RNA is converted to cDNA by reverse transcription, followed by PCR amplification using specific target gene primers. Detection and monitoring were done in real-time using a TaqMan probe to analyse the amplification of the target genes in the real-time micro-PCR analyser (Bigtec Labs, Bangalore) against the internal controls. To provide a quantitative result, standard values (preset) for every batch are automatically compared to the Ct value of the test sample in the HIV-1/2 chip (Truenat™). A horizontal amplification curve is seen on the screen during the test run for negative samples without amplification (Fig. 3b). At the end of the test run, the HIV-1/2 “DETECTED” or “NOT DETECTED” result is shown in Fig. 3a. Moreover, in positive cases, the Ct values and International Units per millilitre (IU/ml) are displayed on the screen as shown in Fig. 3a.
The validity of the test run is also checked by the internal positive control (IPC), and the amplification is displayed on the device screen. The internal controls (positive and negative controls) were used from the Truenat® control panel II kit (MolBio Diagnostics, India). The eluted RNA was also amplified for HIV-1 (ARTUS, Qiagen, Gmbh Germany) and HIV-2 (ALTONA, Argentina) in real-time PCR (Agilent AriaMx) as per the manufacturer's protocol. The comparison of the viral levels (HIV-1/2) was done from the Truenat™ (micro PCR) device with the ARTUS and ALTONA kits (Agilent real-time PCR) in the same samples.
Statistical analysis
The Bland–Altman plot represents the agreement between two paired variables measured on the same scale. It is applied to determine the agreement between two procedures or instruments in quantitative analysis. Also, it requires computing the difference between the two measurements (bias) and plotting it against their average. Therefore, the assumption of the two methods roughly represents the same results for each measured data. However, the limits of agreements have been used to determine the mean difference, which is approximately 1.96 times the standard deviation of the differences. Even a thorough assessment of the agreement requires a comparison of the two methodologies to make an understanding of any systematic or proportionate biases19. The significance of the tests was analysed using a student t-test. The scatter plot depicts the two quantitative relational variables for the same sample20. The scatter plot, combined with the Bland–Altman plot, visualises the two quantitative related variables for the same sample. This integrated methodology ensures a thorough review of method agreement, contributing to this study's outcomes and dependability.
Ethics approval
The study was approved by the AIIMS Institutional Review Board of Ethics Committee (AIIMS, New Delhi, India). The ethical clearance number was IEC-270/01.04.2022, RP-08/2022, and dated 09.04.2022.
Consent to participate
Written informed consent was obtained from each participant prior to recruiting in the study. All investigations and procedures were done as per standard guidelines.
Results
To study the viral RNA load in HIV infected patients, we tested the samples from 110 subjects. After the confirmation of HIV serology, viral RNA was isolated using a Qiagen Kit and then underwent real-time PCR for the target gene amplification. NIBSC (WHO) standards were used for HIV-1/2 while processing the reaction for real-time PCR. Compared to the Qiagen kit for viral extraction and real-time PCR, Truenat™ has a turnaround time of less than 1.5 h and 1500 copies/ml of plasma LOD. One hundred ten samples were processed to assess the sensitivity and specificity of the Truenat™ for HIV-1/2 assay. The reaction assay was performed in Agilent AriaMx real-time PCR system for Qiagen extracted RNA samples. The amplification plot of HIV-1 and HIV-2 positive samples is shown in Fig. 3c, d. Extracted RNA was quantified using the Truenat™ micro-PCR system. The accuracy of the Truenat™ HIV-1/2 assay was determined by comparing the ARTUS HIV-1 RG RT-PCR kit for HIV-1 and the ALTONA real star HIV-2 RT-PCR kit for HIV-2. Bland-Altmann analysis was done to compare methods and correlation between micro-PCR and real-time PCR.The results are indicated in Fig. 4a, b, c. The viral load was compared with three micro-PCR devices (EVH01, EVH02, EVH03). The mean difference between Artus and different lots of Truenat™ tests is 0.4 log IU/ml for EVH01, 0.41 log IU/ml for EVH02 and 0.36 log IU/ml for EVH03, respectively. These values were less than the clinically significant difference of 0.5 log IU/ml. All samples were run in triplicates with the three different devices. The inter-lot variation of viral load determinationis shown in Fig. 4d. Moreover, the average deviation was similar with other lots of Truenat™ (0.13 log IU/ml), which was in the acceptable range as these values are less than 0.5 log IU/ml. However, the mean difference between the Altona kit and the different lots of Truenat™ HIV-2 levels were 0.16 log IU/ml for EVH01, 0.17 log IU/ml for EVH02 and 0.19 log IU/ml for EVH03, respectively. They were also found to have less than 0.5 log IU/ml difference, as shown in Fig. 5a, b, c. The Interlot variation in HIV-2 viral load estimation is shown in Fig. 5d. The average deviation in viral load estimation between different lots of Truenat™ HIV-1/2 tests was 0.13 log IU/ml and 0.24 log IU/ml, respectively. It was also acceptable as these values are less than a clinically significant variation of 0.5log IU/ml. The correlation coefficient (r) for the micro-PCR and Q-PCR is 99%, which had a very strong relationship between these two methods, as shown in Fig. 6a. The sensitivity, specificity and accuracy were ~ 100% (95% CI 86.77–100%), ~ 100% (95% CI 93.94–100%) and ~ 100% (95% CI 95.77–100%), respectively between Truenat™ viral load and Artus HIV-1 Q-PCR viral load in the same samples as shown in Table 1. Similarly, the sensitivity, specificity and accuracy were ~ 100% (95% CI 86.28–100%), ~ 100% (95% CI 93.94–100%) and ~ 100% (95%CI 95.77–100%), respectively, between Truenat™ viral load and Altona HIV-2 Q-PCR viral load in the same samples as shown in Table 2.
Accuracy of truenat™ HIV-1 and HIV-2 assay
Accuracy was determined by RNA extraction and Truenat™ HIV-1/2 PCR for different sample titers for five consecutive days. The accuracy of the Truenat™ HIV-1/2 assay, which quantitatively estimates the amount of HIV-1 and HIV-2 virus using three different lots of reagents, was also determined compared to Artus HIV-1 RG Q-PCR and Altona real star HIV-2 RT-PCR assay kit. The Bland–Altman plot of the method comparison shows that the mean difference between the tests is 0.23 Log IU/mL, less than the clinically significant difference of 0.5 Log IU/mL. The Correlation coefficient (r) for the micro-PCR Truenat™ method is 99%, which shows a strong relationship between the methods. The micro-PCR Truenat™ reaction was performed on three devices of a different lot to find the inter-lot deviation, and the average deviation in HIV-1 RNA and HIV-2 RNA estimated was 0.37 IU/mL and 0.45 IU/ml, respectively. This is acceptable as the values are less than the clinically significant variation of 0.5 IU/mL in both cases.
Linearity
The linearity analysis was performed according to the CLSI guidelines. Serial HIV-1 and HIV-2 RNA dilutions were performed from 1.0 × 108 copies/ml to 1.0 × 102 copies/ml. Nucleic acids were extracted three times with TruePrep™ Auto Sample Prep for each dilution, followed by PCR on Truenat™ (TruePrep™ AUTO/AUTO v2). For HIV-1 and HIV-2 RNA, the assay is linear over eight digits [1.0 × 108 copies / mL to 1.0 × 102 copies/mL]and [1.0 × 108 copies/mL to 1.0 × 102 copies/mL], respectively.
Limit of detection
The LOD was determined by testing dilutions of HIV 1 and HIV-2 NIBSC International Standard diluted in Negative human plasma. The evaluation was performed according to CLSI guidelines. Probit analysis of the data was used to determine the concentration of the RNA that could be detected with a positivity rate of 95%, as shown in Fig. 6b, c. The LOD for HIV-1 with NIBSC 4th International Standard was found to be 635 IU/mL (95% CI 533–826), and the LOD for HIV-2 with 2nd WHO International Standard was found to be 1372.80 IU/mL (95% CI 1134.17–1836.01) by the Truenat™ HIV-1/HIV-2 test.
Precision
Accuracy was tested using the Truenat™ HIV Assay for High, Medium and Low titers of HIV-1 and HIV-2 RNA were administered for five consecutive days. Each day, PCR was performed twice for each HIV-1/2 RNA titer. The standard deviations were within the 0.5 log IU/mL range the Truenat™ HIV-1/2 assay allowed.
Robustness
Potential sample carryover within the Truenat™ HIV-1 and HIV-2 assay was assessed by alternating positive and negative samples. The number of samples run was 10 positive and 10 negative. The results showed that there was no carryover contamination.
Clinical specificity
The 59 negative runs are correlated between the methods and show 100% specificity for the Truenat™ HIV-1 and HIV-2 assay.
Analytical specificity (cross-reactivity)
The cross-reactivity of the test was evaluated using samples negative to HBsAg, anti-HCV, coinfection of HCV & HIV both and HBV-RNA markers but positive to the virus that may have cross-reactivity or coinfected with HIV-1/2. Ten serum samples positive for HCV RNA and 5 serums for co-infection of HCV and HIV RNA were analysed in the cross-reactivity study.
Clinical sensitivity
Positive samples (HIV-1: 25 and HIV-2: 26) were run and correlated between the methods, resulting in 100% sensitivity to the Truenat™ HIV-1/2 assay.
Concordance
A satisfactory agreement [> 95% within log variation] was observed between the viral load determined by the Truenat™ HIV-1/2 assay and the Artus and Altona internal HIV assay.
Discussion
In this study, we have compared the simultaneous detection of HIV-1 and HIV-2 in the Truenat™ system, as previously, there were no platforms available for detecting both Viral loads in a single reaction. However, the measuring of HIV-1 and HIV-2 viral load is essential for monitoring HIV infected patients. There is an increasing tendency to understand the pathophysiology of nucleoside or nucleotide analogue drugs, but it still needs to be clarified to define the viral load dynamics21. HIV viral load monitoring can predict the suppression of the immune system; therefore, the patients have compromised immune effector functions and antibody-dependent cytotoxicity (ADCC) activity22.
Therefore, developing new-generation, dual-target nucleic acid testing (NAT) assays is an essential step for improving the accuracy of HIV assays and limiting the risk of under-quantification8. These new assays must accurately detect and quantify HIV-1/2 RNA in samples, exhibit a lower limit of detection (LLOD) and lower limit of quantification (LLOQ) values comparable with the currently available tests, and show good analytical performance23. A susceptible, specific, and robust micro-PCR device for quantification, targeting the detection of both HIV-1 and HIV-2, has been developed that can simultaneously determine viral load in HIV infected individuals. In addition, rapid release of results is required for treating and monitoring patients under ART14,24. We have isolated the viral RNA from TruePrep™ AUTO/AUTO v2 Universal cartridge-based sample prep extractor device and Qiagen RNA kit. The TruePrep™ Auto is an electromechanical device with a 2-line LCD screen showing RNA isolation status. This device is designed for gradual heat, mixing, and adding reagents to the cartridge's contents as it is placed into the holder. Subsequently, nucleic acid materials are eluted in the Elution chamber. The RNA quality and quantity were almost equal in both the isolation processes after the measurement from the Nanodrop spectrophotometer. Truenat™ is a novel portable real-time micro-PCR similar to real-time PCR (Agilent). This device works on chip-based containing dried MgCl2, internal controls and dried RT-PCR reagents for real-time amplification to detect the HIV-1/2 virus. The Truenat™ HIV-1/2 chip also stores information about the used chip to prevent any accidental reuse of the chip.110 patients were evaluated from both (micro-PCR and real-time PCR) devices, and our results had higher precision, specificity and linearity across a wide dynamic range for HIV-1 and HIV-2 viral loads. Bland-Altmann plot analysis showed that the viral loads from TruenatTM PCR meet with the real-time PCR. The Bland-Altmann mean difference for the comparison was 0.36–0.41 log IU/ml from the micro-PCR devices for the HIV-1 virus, and for the HIV-2 virus, the mean differences were from 0.16 to 0.19 log IU/ml. In addition, the Pearson correlation coefficient value shows a strong correlation between these two devices. Our results have shown 100% sensitivity and specificity compared to real-time PCR. Notably, the tests showed good linearity and reproducibility in triplicates from 2 to 6 log copies/mL25, relevant ranges for clinical decision making. This accurate test is thus reliable for treatment monitoring of patients with HIV.
Researchers have attempted many methods to simplify PCR and real-time PCR platforms to develop nucleic acid amplification26. Recently, micro-PCR TruenatTM was used to detect HBV viral loads, diagnose HBV infection, and monitor drug efficacy27. Micro-PCR Truenat™ was also reported for the detection of M. tuberculosis, Malaria, Papillomavirus, Beta-CoV and SARS-CoV-2 with asensitivity of 94.7% (95% CI 89.8, 97.6), 99.3% (95% CI 95.5, 99.9), 97.5% (95% CI 86.8, 99.9) and 100% respectively28,29,30,31.
Furthermore, the focus must be heavily oriented to reach this technology to remote areas, which will help to assess early detection of care for multimorbidity and good quality of life. Studies have shown that HIV-positive patients are more prone to develop cardiovascular diseases and preserved ejection fraction32,33,34,35,36. Overall, this device will help to monitor the viral load of HIV-1/2 and provide insight into developing therapeutic and preventive vaccines, novel immunotherapies and an early cure for HIV infected patients.
Limitation and future
This device has limitations, particularly where the patient number is higher, as this device can run a maximum of 4 samples in a batch. In this study, we found that the HIV detection limit for HIV-1 and HIV-2 was 635 and 1372.8 IU/mL. It requires further research and validation up to a lower detection limit. Multicentric studies are required to address the challenges of variable mutations in the population.
Conclusion
The healthcare system needs to address the challenges of HIV infection where the detection facility is not available, particularly in remote areas. Our study suggests that this device is cost-effective, easy to handle, battery-operated, accurate, and can be performed for routine uses in remote places and places where well-developed infrastructure and sophisticated equipment are unavailable. Overall, TruePerp™ and Truenat™ devices can detect both HIV-1 and HIV-2 in a single reaction. To the best of our knowledge, this is the novel portable system for quantitating nucleic acids.
Data availability
The corresponding author, Shyam Prakash, will provide data supporting the research findings upon a feasible request.
References
Wiegand, A. & Maldarelli, F. Single-copy quantification of HIV-1 in clinical samples. Methods Mol. Biol. 1087, 251–260 (2014).
WHO report. HIV Global Situtations and Trends. (2023).
UNAIDS/WHO estimates, 2023. HIV data and statistics. (2023).
German Advisory Committee Blood (Arbeitskreis Blut), S. ‘Assessment of P. T. by B. Human Immunodeficiency Virus (HIV). Transfusion medicine and hemotherapy : Offizielles Organ der Deutschen Gesellschaft fur Transfusionsmedizin und Immunhamatologie. 43 203–222 https://doi.org/10.1159/000445852 (2016).
WHO. HIV and AIDS. (2023)https://www.who.int/news-room/fact-sheets/detail/hiv-aids
Kannangai, R. et al. Molecular confirmation of human immunodeficiency virus (HIV) type 2 in HIV-seropositive subjects in south India. Clin. Diagn. Lab. Immunol. 7, 987–989 (2000).
Rübsamen-Waigmann, H. et al. Spread of HIV-2 in India. Lancet 337, 550–551 (1991).
Kanki, P. J., Peeters, M. & Guéye-Ndiaye, A. Virology of HIV-1 and HIV-2: Implications for Africa. AIDS 11(Suppl B), S33-42 (1997).
Ehret, R., Harb, K., Breuer, S. & Obermeier, M. Performance assessment of the new Xpert® HIV-1 viral load XC assay for quantification of HIV-1 viral loads. J. Clin. Virol. Off. Publ. Pan Am. Soc. Clin. Virol. 149, 105127 (2022).
Engstrom-Melnyk, J., Rodriguez, P. L., Peraud, O. & Hein, R. C. Clinical applications of quantitative real-time PCR in virology. Methods Microbiol. 42, 161–197. https://doi.org/10.1016/bs.mim.2015.04.005 (2015).
Barnett, D., Walker, B., Landay, A. & Denny, T. N. CD4 immunophenotyping in HIV infection. Nat. Rev. Microbiol. 6, S7-15 (2008).
Neogi, U. et al. Dried blood spot HIV-1 RNA quantification: A useful tool for viral load monitoring among HIV-infected individuals in India. Indian J. Med. Res. 136, 956–962 (2012).
Drain, P. K. et al. Point-of-care HIV viral load testing: an essential tool for a sustainable global HIV/AIDS response. Clin. Microbiol. Rev. 32, 10–1128 (2019).
Mauk, M. et al. Miniaturized devices for point of care molecular detection of HIV. Lab Chip 17, 382–394 (2017).
Günthard, H. F. et al. Antiretroviral drugs for treatment and prevention of HIV infection in adults: 2016 recommendations of the international antiviral society-USA panel. JAMA 316, 191–210 (2016).
Tanriverdi, S., Chen, L. & Chen, S. A rapid and automated sample-to-result HIV load test for near-patient application. J. Infect. Dis. 201(Suppl), S52–S58 (2010).
Kit, A. Immunodeficiency Virus type 1 pol gene region DNA testing Everything ... Everyone ... Everywhere ... Introduction to Human Immunodeficiency Virus. 1–13 (2016).
Bertine, M. et al. New highly sensitive real-time pcr assay for HIV-2 group A and group B DNA quantification. J. Clin. Microbiol. 55, 2850–2857 (2017).
Roberts, T., Cohn, J., Bonner, K. & Hargreaves, S. Scale-up of routine viral load testing in resource-poor settings: Current and future implementation challenges. Clin. Infect. Dis. Off. Publ. Infect. Dis. Soc. Am. 62, 1043–1048 (2016).
Riffenburgh, R. H. & Gillen, D. L. Techniques to aid analysis. Stat. Med. https://doi.org/10.1016/b978-0-12-815328-4.00027-9 (2020).
Moore, D. S., Notz, W. & Fligner, M. A. The Basic Practice of Statistics TA-TT (W.H. Freeman and Co, 2013).
Sitnik, R., Paes, Â., Mangueira, C. P. & Pinho, J. R. R. A real-time quantitative assay for hepatitis B DNA virus (HBV) developed to detect all HBV genotypes. Rev. Inst. Med. Trop. Sao Paulo 52, 119–124 (2010).
Yucha, R. et al. Higher HIV-1 Env gp120-specific antibody-dependent cellular cytotoxicity (ADCC) activity is associated with lower levels of defective HIV-1 provirus. Viruses 15, 1–18 (2023).
Le Gal, F. et al. Performance characteristics of a new consensus commercial kit for hepatitis D Virus RNA viral load quantification. J. Clin. Microbiol. 55, 431–441 (2017).
World Health Organization. Hiv Prevention, Testing, Treatment, Service Delivery and Monitoring. (2021).
Anderson, E. M. & Maldarelli, F. Quantification of HIV DNA using droplet digital PCR techniques. Curr. Protoc. Microbiol. 51, e62 (2018).
Bodulev, O. L. & Sakharov, I. Y. Isothermal nucleic acid amplification techniques and their use in bioanalysis. Biochemistry 85, 147–166 (2020).
Prakash, S., Bharti, S. & Priyatma, A. R. Performance Characteristic of a simple, rapid and cost-effective micro-PCR assay for HBV DNA quantification. J. Med. Diagn. Meth. 12, 434 (2023).
Nikam, C. et al. Evaluation of the Indian TrueNAT micro RT-PCR device with GeneXpert for case detection of pulmonary tuberculosis. Int. J. Mycobacteriol. 3, 205–210 (2014).
Nair, C. B. et al. Differential diagnosis of malaria on Truelab Uno®, a portable, real-time, MicroPCR device for point-of-care applications. PLoS One 11, 1–14 (2016).
Hariprasad, R. et al. Evaluation of a chip-based, point-of-care, portable, real-time micro pcr analyzer for the detection of high-risk human papillomavirus in uterine cervix in India. JCO Glob. Oncol. https://doi.org/10.1200/go.20.00024 (2020).
Basawarajappa, S. G. et al. Performance evaluation of TruenatTM Beta CoV & Truenats SARS-CoV-2 point-of-care assays for coronavirus disease 2019. Indian J. Med. Res. 153, 144–150 (2021).
Freiberg, M. S. et al. HIV Infection and the risk of acute myocardial infarction. JAMA Intern. Med. 173, 614–622 (2013).
Freiberg, M. S. et al. Association between HIV infection and the risk of heart failure with reduced ejection fraction and preserved ejection fraction in the antiretroviral therapy era: Results from the veterans aging cohort study. JAMA Cardiol. 2, 536–546 (2017).
Tseng, Z. H. et al. Sudden cardiac death in patients with human immunodeficiency virus infection. J. Am. Coll. Cardiol. 59, 1891–1896 (2012).
Beckman, J. A. et al. Association of human immunodeficiency virus infection and risk of peripheral artery disease. Circulation 138, 255–265 (2018).
Chow, F. C. et al. Comparison of ischemic stroke incidence in HIV-infected and non-HIV-infected patients in a US health care system. J. Acquir. Immune Defic. Syndr. 60, 351–358 (2012).
Acknowledgements
The authors are grateful to the AIIMS New Delhi, India, Director for providing the infrastructure and library facility and to the secretary of the Ethics Committee for providing the ethical clearance for conducting the research work. Thanks to Bigtec Labs, Bangalore, India, for providing the micro-PCR, extractor, and Chips for HIV quantification and reagents, including buffers. Moreover, the authors appreciate the support and assistance from our lab colleagues during the study in the AIIMS, New Delhi, India.
Funding
This study was supported by Intramural grants from the AIIMS (A-COVID-9).
Author information
Authors and Affiliations
Contributions
S.P. has developed the conceptual framework and structure of the study. S.P., P., M.S, and R.A. performed the experiments, data collection and analysis. M. and S.K. did the counselling and collection of the patient samples. S.P and R.A. wrote the manuscript & first draft. The final manuscript has been read, edited and approved by each author. Bigtec Labs, Bangalore, develops devices for extracting RNA and chip-for HIV-1 and HIV-2 in micro-PCR.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Prakash, S., Aasarey, R., Priyatma et al. The development, evaluation, performance, and validation of micro-PCR and extractor for the quantification of HIV-1 &-2 RNA. Sci Rep 14, 8700 (2024). https://doi.org/10.1038/s41598-024-56164-5
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-024-56164-5
Keywords
Comments
By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.