Name: Author Spotlight: Addressing Regulatory Gaps in Molecular Studies by Quantifying Viral Vectors in Complex Matrices
Uploaded: 2023-07-14T14:50:00
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Description: Watch this Scientific Journal Video about Addressing Regulatory Gaps in Molecular Studies by Quantifying Viral Vectors in Complex Matrices at JoVE.com

We would like to thank Nick Russell and Brandon McKethan of Bio-Rad for their helpful discussions during the development of this method.

Quantification of Viral Vectors in Tears Using ddPCR for Bioshedding Studies

<ol>
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N., Loker, R. N. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=qPCR+and+qRT-PCR+analysis:+Regulatory+points+to+consider+when+conducting+biodistribution+and+vector+shedding+studies.">qPCR and qRT-PCR analysis: Regulatory points to consider when conducting biodistribution and vector shedding studies.</a> Molecular Therapy. Methods &amp; Clinical Development. 17 (20), 152-168 (2020).</li><li>Wissel, M. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Recommendations+on+qPCR/ddPCR+assay+validation+by+GCC.">Recommendations on qPCR/ddPCR assay validation by GCC.</a> Bioanalysis. 14 (12), 853-863 (2022).</li><li>Expectations for biodistribution (BD) assessments for gene therapy (GT) products. 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E. <a target="_blank" href="http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?db=PubMed&cmd=Search&doptcmdl=Citation&defaultField=Title+Word&term=Accurate+quantification+of+AAV+vector+genomes+by+quantitative+PCR.">Accurate quantification of AAV vector genomes by quantitative PCR.</a> Genes. 12 (4), 601 (2021).</li><li>Ai, J., Ibraheim, R., Tai, P. W. 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All authors are employees of KCAS Bioanalytical and Biomarker Services, a contract research organization providing comprehensive Good Laboratory Practices/Good Clinical Practices compliant development services from early discovery support through product registration, including supporting AAV-based assays, as described in this protocol. KCAS funded this project and publication of this protocol. While there are no current FDA guidelines for the design and validation of the experiments presented in this paper, the experts and thought leaders developing such studies at KCAS have adopted this approach as the baseline approach. Additional criteria and parameters are discussed on a project-by-project basis and may be included based on the intended use.

There are several steps of the ddPCR protocol that are critical to proper performance of the assay. The first critical step is the design and optimization of the primers and probe. In general, the use of hydrolysis probe-based chemistry over dye-based chemistry (e.g., SYBR Green) in a preclinical or clinical setting is recommended due to their superior specificity. Additionally, the choice of amplification target is a critical one. Typically, the transgene of interest of the vector is targeted. However, in earlier preclinical stages or in vectors where it may not be possible to distinguish vector transgene versus genomic DNA, it may be appropriate to use standardized vector targets. For example, one could target the inverted terminal repeat region, promoter, poly-A tail, or the inter-segment junctions between these vector components. The choice of target will vary based on vector design. Traditional qPCR primer and probe design strategies and software are typically appropriate for ddPCR. Design parameters that are expected to yield a consistent annealing temperature (for example, 60&#176;C) should be selected to reduce the amount of optimization required. It has also been recommended to design, order, and evaluate at least three different sets for each target. One should then select the set that shows the greatest specificity (no amplification in the negative control well or in a matrix of related target DNA) and sensitivity (i.e., limit of detection)20.
If it is advantageous to be able to transition the assay between qPCR and ddPCR, it is recommended to optimize the assay conditions using qPCR first, and to identify conditions for the selected set that result in amplification efficiencies of 90%-110% with an R2&#160;&#8805; 0.98. However, ddPCR as an endpoint method is typically less sensitive than qPCR due to variances in amplification efficiencies. At a minimum, it is recommended to run a thermal temperature gradient in the annealing/extension step to cover temperatures above and below the expected annealing temperatures and to evaluate the rain and fluorescent amplitude separation between the negative and positive droplet clusters as a function of temperature. If the workspace allows, it is recommended to have individual dedicated workstations for master mix preparation, template addition, and amplification. Where possible, these should physically be segregated by a unidirectional workflow with built-in engineering controls, such as controlled access and differential air pressures, to reduce the risk for cross contamination and false positives. If this is not possible, extreme caution must be taken to prevent cross contamination.
There are two steps in this protocol that may appear unusual to those who are more accustomed to qPCR assay development. The first is the inclusion of a restriction enzyme in the PCR master mix. During ddPCR amplification, each droplet is thermocycled to endpoint. In a properly optimized assay, this results in two populations of droplets, one set displaying a consistently high level of fluorescent signals-the positives-and another consistently displaying a low level of fluorescent signal-the negatives. If PCR interference occurs, it may desynchronize the initiation of PCR amplification, resulting in the droplet not reaching an amplification plateau, and thus inconsistent fluorescent endpoints. In this case, the droplets will be distributed between the negatives and positives, resulting in a phenomenon called ddPCR rain. This can result in inaccurate quantification of the target and inconsistently and subjectively applied thresholds. Our recommendation to set the threshold slightly above the signal of the NTC, which should minimize the effects of rain in the final quantification as all droplets are still considered positive, even if not fully cycled to endpoint. AAVs have a highly complex secondary structure that, depending on the amplification target, may reduce accessibility to the primers and probes, resulting in PCR interference and thus rain. The inclusion of the restriction enzyme in the master mix cleaves this secondary structure to increase access by the primers and probes, reducing the rain, which may thereby improve the accuracy of the assay. The effects of the inclusion of a restriction enzyme in the ddPCR reaction have been described previously25,32. Any restriction enzyme can be used, so long as it is confirmed to not cut within the target amplification region. No predigestion steps or alternative buffer compositions are required.
The second unusual step is the preparation of the tear sample containing AAV. In this protocol, a 1:10 (or greater) ratio of tears was utilized and subsequently the sample was heated. Typically, when tears are collected via a capillary tube, which is a widely utilized collection method, on average approximately 10.0 &#181;L can be collected33. The dilution helps to address the limited sample volume and provide enough material for duplicate well testing. While this does reduce the theoretical limit of detection, the robust sensitivity of ddPCR should still result in the detection of all but an extremely few number of vector particles. This approach additionally creates a &#34;backup&#34; well if one were to unexpectedly fail. In this case, or in cases of insufficient sample volume to run two wells, the Poisson error could be used to assess precision. Furthermore, in cases where the concentration is below the limit of detection, it creates an opportunity to merge well data to determine a concentration. It is necessary to liberate the AAV vectors from the viral capsids for ddPCR detection. Some methods for the quantification of AAV have included a proteinase K digestion step to remove the viral capsid34,35,36. All naturally occurring AAV serotypes have melting temperatures at or below approximately 90 &#176;C, with most falling below 80 &#176;C; therefore, this appears to be an unnecessary inclusion37. Heating alone appears to be sufficient to release vector DNA.
Furthermore, ddPCR is generally less susceptible to PCR inhibitors that may be present in a sample that may affect a qPCR assay. If a specific DNA isolation step is included, this would also require specific validation, which is avoided in this protocol. Samples are diluted prior to heating due to the kinetics of diffusion of the vector genomes in a liquid. During the heating and subsequent cooling process, the positive and negative sense strands of the single-stranded DNA genome can anneal together to produce a double-stranded intermediate if the concentrations are sufficiently high. Dilution prior to heating reduces the concentrations and makes it mathematically unlikely that enough double-stranded intermediates form to have an adverse effect on the accuracy of quantification. It should be noted that the synthetic DNA fragments or linearized plasmids used as quality controls must not undergo this heating step. As these are double-stranded, heating would result in conversion to single-stranded intermediates. Following independent partitioning of these single-stranded QCs into droplets, this would be expected to result in a twofold increase in QC concentration relative to the nominal concentration. Alternatively, if QCs are to be heated to standardize the method, this must be factored into the reconstitution and assignment of a nominal concentration.
Finally, with regards to sample preparation, many protocols also recommend the inclusion of a DNase treatment step to remove any unencapsidated vector DNA. This step is critical in cases where it is not desired to quantify free DNA associated with the vector preparation (such as during quantification for dosage purposes). However, in the context of biodistribution and bioshedding studies, one typically desires to know where any vector DNA has traveled, regardless of if it is encapsidated or not. Therefore, it is suggested to typically not perform a DNase treatment step during such studies. If it is determined to be necessary to include a DNase step, this step should be prior to dilutions and heating.
In this paper, data representative of the approach to assessment of the dynamic range, sensitivity, accuracy, and precision of the method within the context of a fit-for-purpose, good laboratory practice compliant validation are presented. The current lack of guidance on this topic leaves validating laboratories to determine target assay criteria for themselves, in line with current industry thinking. Different groups have posed both higher and lower target criteria than used in this study19,20,21,22,23,24,25. The target assay criteria, until more rigidly defined, should be selected prior to validation based on the intended clinical applications of the method. Depending on the downstream decisions to be made on the basis of the data, higher levels of accuracy and precision may be needed. Conversely, a simple positive versus negative result may be sufficient.
The approach also addressed recommendations for the assessment of specificity and a matrix effect. A pool of tears collected from untreated individuals failed to produce a positive result in this assay, whereas the target could be detected when the vector was spiked into the tears at a high and low concentration within the recommended recovery rates. Ideally, matrix containing endogenous vector (e.g., collected following treatment with viral vector) would also be included in these assessments. However, it is unlikely that such samples will be available for use in a validation. To increase the robustness of the validation, multiple pools of tears, or tears collected from a variety of individuals, could be assessed to determine if a patient-specific matrix effect occurs. Finally, it is recommended to evaluate the stability. In workflows where DNA extraction occurs out of the biological matrix, it may be necessary to evaluate the stability of both the sample and the extracted DNA. In this workflow, the sample is tested directly in the assay without the need for DNA extraction. Therefore, in consideration of the evaluation of the stability for this method, one must evaluate the stability of the tear samples. Typically, benchtop, refrigerator, freeze/thaw, and long-term stability assessments are recommended. These were not performed as part of this study, but the methods developed here can be used in this assessment, following manipulations to the input samples.
Overall, this method has been demonstrated to be a robust, repeatable, and validatable assay to detect AAV-based vectors in tear samples. It may serve as a platform to be adapted to specific vectors to support clinical trials and provides a basis for validation of an assay consistent with good laboratory practices.

Gene therapy definitions vary, but generally induce an intentional and often expected permanent alternation of a specific DNA sequence of the cellular genome to modify or manipulate the expression of a gene or to alter the biological properties of a living cell for a clinical purpose1,2. Viral vectors are increasingly being used as vehicles for gene therapy due to their efficiency of transduction, with one report suggesting that over 70% of current gene therapy clinical trials utilize viral vectors3. Interest in viral vectors for gene therapy has been gaining steadily. The Quarter 4 2022 Quarterly Data Report on the Gene, Cell, and RNA therapy landscape from the American Society of Gene and Cell Therapy reported that in 2022, the gene, cell, and RNA therapy pipeline from preclinical to pre-registration grew by 7%, bringing the total number of therapies in development to 3,726, of which 2,053 (55%) were gene therapies4. The United States Food and Drug Administration (USA FDA) currently has approved 27 cell and gene therapies for clinical use in humans, five of which specifically utilize viral vectors5.
Adeno-associated viruses (AAVs) have gained specific interest as vehicles for gene therapy. A recent meta-analysis revealed that there have been approximately 136 clinical trials investigating the use of AAVs in the past two decades6. Additionally, three of the five USA FDA approved gene therapies are AAV based. This is due to their highly editable nature, broad host range that can be tuned based on the use of specific naturally occurring or artificially engineered vectors, low pathogenicity and toxicity in humans, and generally low immunogenicity7,8. AAVs have also been successfully used to treat ocular diseases in an approved clinical setting. Voretigene neparvovec-rzyl is an AAV2-based therapy that was approved by the USA FDA in 2017 and by the European Medicines Agency (EMA) in 2018 to treat biallelic RPE65 mutation-associated retinal dystrophy9.
With increasing interest in the development of AAV-based therapies comes the need for regulatory guidance on assays. Accurate detection and quantification of any viral vector is an integral part of the discovery, manufacturing, and preclinical/clinical testing phases of product development. The USA FDA has begun to issue some guidance for gene therapies, including on the chemistry, manufacturing, and control for human gene therapy investigational new drug applications10, long-term follow-up after administration of gene therapy11, replication-competent retrovirus testing12, and recommendations for microbial vectors used in gene therapies13. The EMA has also released a series of guidelines concerning the development of gene therapy products that generally align with the FDA recommendations, though some differences do exist14. It is important to note that while these guidance do not establish legally enforceable responsibilities, except where specific regulations are referenced, they provide clarity on the current thinking from regulatory agencies on the topic and their expectations for assays required for drug filings and regulatory approval.
The FDA specifically recommends that studies should be conducted to assess the distribution, persistence, and clearance of a vector from the site of administration to target ocular and non-ocular tissues, intraocular fluids, and blood15. These take the form of biodistribution and shedding studies. Biodistribution studies evaluate exposure by investigating how a product is spread throughout a patient&#39;s body from the site of administration. Shedding specifically evaluates the release of the product from the patient into the environment and raises the possibility of transmission of the vector to untreated individuals16. The FDA makes recommendations for the design of biodistribution and shedding studies with respect to the frequency of sample collection, duration of sample collection, types of samples collected, and storage conditions.
Additionally, the FDA recommends the use of quantitative polymerase chain reaction (qPCR, or real-time PCR) for the quantitative detection of vector genomes due to its ease of performance, high-throughput format, rapid turnaround times, and assay sensitivity. However, there is a relative lack of recommendations for the design and performance assessment of molecular methods compared to those which exist for small and large molecules. Many of the guidelines for such studies are difficult to apply to molecular methods due to the unique and complex design of both the products and the assays themselves, raising questions as to the appropriateness of the available platforms for the recommended assessments and appropriate methods for assay validation. To date, the FDA has not required formal validation of PCR-based assays, though the EMA has imposed this requirement17. In light of this void, different groups and workshops have issued white papers and recommendations that manufacturers and contract research organizations have sought to follow18,19,20,21,22,23,24,25. Most of these recommendations are written specifically with qPCR assays in mind, with suggestions or alterations for emerging platforms, such as droplet digital PCR (ddPCR), included only as deemed relevant. More recent recommendations have focused on considerations for ddPCR assays, but have largely focused on their applications to vector genome quantification in a manufacturing setting rather than in the complex biological matrices encountered in bioshedding studies.
Depending on clinical application and goals, ddPCR may be preferred over qPCR in support of biodistribution and shedding studies due to ddPCR&#39;s increased sensitivity and ability to handle matrix interference compared to qPCR. Furthermore, due to the partitioning of samples into approximately 20,000 droplets, accurate quantification of the copy number can be achieved without the use of a standard curve using Poisson statistics, simplifying the method development and validation. The goal of this protocol is to describe a standardized approach for the development and validation of a ddPCR-based method for the detection of AAV vectors in tears collected from the ocular surface in support of clinical bioshedding studies.

<table border="1" fo:keep-together.within-page="1" fo:keep-with-next.within-page="always">
	<tbody>
		<tr>
			<td>AAV-eGFP Vector</td>
			<td>Charles River Laboratories</td>
			<td>RS-AAV2-FL</td>
			<td>Lot AAV2-0720-FL, used as a proof of principle vector</td>
		</tr>
		<tr>
			<td>AutoDG Droplet Digital PCR system</td>
			<td>Bio-Rad</td>
			<td>QX200</td>
			<td>Alternative ddPCR system may be used following manufacturer&#8217;s protocol.</td>
		</tr>
		<tr>
			<td>AutoDG Oil for Probes</td>
			<td>Bio-Rad</td>
			<td>1864110</td>
			<td>Or use material compatible with ddPCR system.</td>
		</tr>
		<tr>
			<td>ddPCR Buffer Control for Probes</td>
			<td>Bio-Rad</td>
			<td>1863052</td>
			<td>Or use material compatible with ddPCR system and PCR chemistry.</td>
		</tr>
		<tr>
			<td>ddPCR Droplet Reader Oil</td>
			<td>Bio-Rad</td>
			<td>1863004</td>
			<td>Or use material compatible with ddPCR system.</td>
		</tr>
		<tr>
			<td>ddPCR Piercable Foil Seals</td>
			<td>Bio-Rad</td>
			<td>1814040</td>
			<td>Or use material compatible with ddPCR system.</td>
		</tr>
		<tr>
			<td>ddPCR Plates 96-Well, Semi-Skirted</td>
			<td>Bio-Rad</td>
			<td>12001925</td>
			<td>Or use material compatible with ddPCR system.</td>
		</tr>
		<tr>
			<td>ddPCR Supermix for Probes (no dUTP)</td>
			<td>Bio-Rad</td>
			<td>1863023, 1863024, or 1863025</td>
			<td>Use master mix compatible with primers/probes and ddPCR system.</td>
		</tr>
		<tr>
			<td>DG32 AutoDG Cartidges</td>
			<td>Bio-Rad</td>
			<td>1864108</td>
			<td>Or use material compatible with ddPCR system.</td>
		</tr>
		<tr>
			<td>Droplet Reader</td>
			<td>Bio-Rad</td>
			<td>QX200</td>
			<td>Alternative ddPCR system may be used following manufacturer&#8217;s protocol.</td>
		</tr>
		<tr>
			<td>GeneAmp PCR Buffer</td>
			<td>Applied Biosystems</td>
			<td>N8080129</td>
			<td>N/A</td>
		</tr>
		<tr>
			<td>Nuclease-Free Water</td>
			<td>Ambion</td>
			<td>AM9906</td>
			<td>N/A</td>
		</tr>
		<tr>
			<td>PCR Plate Sealer</td>
			<td>Bio-Rad</td>
			<td>PX1</td>
			<td>Or use material compatible with ddPCR system.</td>
		</tr>
		<tr>
			<td>Pipet Tips for AutoDG</td>
			<td>Bio-Rad</td>
			<td>1864120</td>
			<td>Or use material compatible with ddPCR system.</td>
		</tr>
		<tr>
			<td>Pluronic F-68 Non-ionic Surfactant</td>
			<td>Gibco</td>
			<td>24040</td>
			<td>N/A</td>
		</tr>
		<tr>
			<td>Primer and Hydrolysis Probes</td>
			<td>Various</td>
			<td>Various</td>
			<td>Design based on target sequence using general approaches for primer/probe design. Select fluorphores and quenchers compatible with ddPCR system.</td>
		</tr>
		<tr>
			<td>Restriction Enzyme</td>
			<td>Various</td>
			<td>Various</td>
			<td>Varies with target amplification sequence. Use restriction enzyme that does not cut in the amplified sequence</td>
		</tr>
		<tr>
			<td>Sheared salmon sperm DNA</td>
			<td>ThermoFisher</td>
			<td>AM9680</td>
			<td>N/A</td>
		</tr>
		<tr>
			<td>Synthetic DNA gene fragment or linearized plasmid</td>
			<td>Various</td>
			<td>Various</td>
			<td>Design a synthetic DNA fragment containing the target amplification region for use as a quality control</td>
		</tr>
		<tr>
			<td>TE Buffer</td>
			<td>Teknova</td>
			<td>T0224</td>
			<td>Ensure prepared or purchases nuclease free. 10 mM Tris-HCl, 1.0 mM EDTA, pH=8.0</td>
		</tr>
		<tr>
			<td>Touch Thermal Cycler</td>
			<td>Bio-Rad</td>
			<td>C1000</td>
			<td>Or use material compatible with ddPCR system.</td>
		</tr>
	</tbody>
</table>

a validatable droplet digital polymerase chain reaction assay for the detection of adeno-associated viral vectors in bioshedding studies of tears

The use of viral vectors to treat genetic diseases has increased substantially in recent years, with over 2,000 studies registered to date. Adeno-associated viral (AAV) vectors have found particular success in the treatment of eye related diseases, as exemplified by the approval of voretigene neparvovec-rzyl. To bring new therapies to market, regulatory agencies typically request qualified or validated bioshedding studies to evaluate release of the vector into the environment. However, no official guidelines for the development of molecular based assays to support such shedding studies have been released by the United States Food and Drug Administration, leaving developers to determine best practices for themselves. The purpose of this protocol is to present a validatable protocol for the detection of AAV vectors in human tears by droplet digital polymerase chain reaction (ddPCR) in support of clinical bioshedding studies. This manuscript discusses current industry approaches to molecular assay validation and demonstrates that the method exceeds the target assay acceptance criteria currently proposed in white papers. Finally, steps critical in the performance of any ddPCR assay, regardless of application, are discussed.

Author Spotlight: Addressing Regulatory Gaps in Molecular Studies by Quantifying Viral Vectors in Complex Matrices 

A Validatable Droplet Digital Polymerase Chain Reaction Assay for the Detection of Adeno-Associated Viral Vectors in Bioshedding Studies of Tears

Our protocol quantifies adeno-associated viral vectors in complex matrices. Accurate detection and quantification are essential to assessing their performance in clinical trials. This protocol specifically seeks to fill the current regulatory gaps in the design of good laboratory practices'compliant molecular studies.As a part of viral vector development, regulatory agencies require the assessment of vector bio-shedding. ddPCR is a promising technology for this assessment as it allows for accurate quantification without the use of a standard curve and improved sensitivity compared to qPCR. Accurate quantification in the complex matrices encountered in clinical settings, such as tears, can be challenging to validate due to PCR interference and inhibition.Limited clinical sample amounts can also limit the ability to detect rare events if the assay is not sufficiently sensitive. Our approach develops a repeatable and adaptable ddPCR-based framework to validate assays for use in regulated studies. This method avoids a specific DNA extraction step, allowing for more streamlined validation and provides clear criteria against which to evaluate assay performance to ensure robustness and repeatability.This protocol has the potential to be applied to any viral vector shedding study, not just the detection of AAV in tears, as presented here. It creates a robust and repeatable framework upon which multiple fit-for-purpose, regulated programs can be developed.

For demonstrative purposes, an assay designed to detect a commercially available, enhanced green fluorescent protein (eGFP)-expressing AAV2 vector, with a synthetic double-stranded DNA fragment containing eGFP as a quality control, was developed. Currently, there is ongoing debate as to whether the vector itself or a synthetic DNA fragment or linearized plasmid is most appropriate for use as the QC. Generally, a synthetic DNA fragment or linearized plasmid may be used if equivalency to the vector is demonstrated in method development (data not shown). Primers and probes were designed and optimized to detect the eGFP transgene. Refer to Supplementary Table S1 for the sequences used in this work. The concentration of the QC fragment stock was empirically determined using ddPCR. All assays were performed using the concentrations and PCR conditions given as examples in the protocol section.
For qPCR assays, it is recommended to evaluate the linearity, sensitivity, dynamic range, accuracy, and precision of the standard curve. Since ddPCR does not rely on a standard curve for target quantification, these recommendations must be modified. Instead, QCs consisting of synthetic double-stranded DNA fragments diluted to various concentrations to span the expected quantifiable range of a ddPCR reaction based on the Poisson statistical modeling were utilized29,30,31,32 to define the dynamic range and sensitivity and to evaluate accuracy and precision. The choice of QC concentrations was based primarily on the expected ratio of positive to total droplets within a well at a given concentration. Mathematically, ddPCR is theoretically most accurate when approximately 80% of the partitions positively amplify. As the positive to total droplet ratio increases above 0.8, the accuracy decreases due to saturation of the partitions, with quantification not being possible once 100% of the droplets are positive. On the low end, theoretically, as little as one positive droplet may be detected and quantified, though the accuracy is poorer and the assay is subject to low-level false positives. Typically, at least three droplets must be positive for a result to be calculated with 95% confidence, which is the threshold to calculate a concentration we used here.
A series of five different QC concentrations was prepared, with the target copy number/&#181;L PCR reaction volumes calculated expected to yield positive to total droplet ratios spanning the quantifiable range of ddPCR, as shown in Table 5. These were used to evaluate the accuracy and precision of the assay. In the assessment here, the upper and lower limits of quantification were not pushed to the theoretical maximum possible in ddPCR. Accurate quantification may be possible at higher and lower levels than demonstrated here. The range should be developed in alignment with the downstream applications of this method.
A total of three independently prepared dilution series of these QCs were prepared in sample dilution buffer for each batch to evaluate the intra-assay accuracy and precision. Duplicate wells of each QC dilution were included. To simulate an actual validation protocol, a total of six accuracy and precision batches were performed by multiple analysts over multiple days. The results from these six batches were analyzed to define the intra-assay and inter-assay accuracy and precision of the method and to define the dynamic range of the assay.
Intra-assay performance was assessed for each batch at each QC level. We expected that all QC and NTC wells would have at least 10,000 droplets. This was met in 216 out of 216 wells tested across all six batches, with an average droplet count of 19,748 droplets/well (Table 6). Next, the inter-well %CV of each set of duplicate wells of each QC was expected to be &#8804;25.0%, except for the upper and lower limit QC, where &#8804;30.0% was expected. This was met in sets of 90 out of 90 wells tested across all six batches for the QCs, with an average inter-well %CV of 3.9% across all the QC levels (Table 7). All QCs yielded mean positive to total droplet ratios within the expected ranges outlined above (Table 6).
Within each batch, the intra-assay mean and standard deviation were calculated for each of the independently prepared dilution series points, and these were used to calculate an intra-assay mean for each concentration in each assay. This was used to assess the accuracy and precision of the assay (Table 8). Precision refers to the variability in the data from replicates of the same homogenous sample under normal assay conditions and is evaluated by calculating the %CV of the multiple included aliquots. We expected that the three aliquots tested within each batch would yield an intra-assay %CV &#8804;25.0%, except for the upper and lower limit QC where &#8804;30.0% was expected. This was met for all five QC levels in each of the 60 batches (30 out of 30 total performances). Generally, greater intra-assay precision than the target criteria could be achieved, with a mean intra-assay %CV of 7.7% across all QC levels. Accuracy refers to the closeness of agreement between the experimentally determined value and the nominal value. This is evaluated by calculating the percent relative error (%RE, or %Bias) between the calculated concentrations of each QC and their theoretically expected nominal concentrations. It was expected that the intra-assay mean of the three aliquots would be &#177;25.0% RE of the nominal concentration, except for the upper and lower limit QC where &#177;30.0% was expected. This was met for all five QC levels in each of the 60 batches (30 out of 30 total performances). Generally, greater intra-assay accuracy than our target could be achieved, with a mean absolute intra-assay %RE of 4.2% across all QC levels. In all performances of the NTC (30 total), no positive droplets were detectable.
Inter-assay accuracy and precision were also calculated using the intra-assay mean of each QC level within each batch. The inter-assay precision was expected to be &#8804;25.0% CV, except for the upper and lower limit QC where &#8804;30.0% was expected. Likewise, for inter-assay accuracy, &#177;25.0% RE was expected, except for the upper and lower limit QC where &#177;30.0% was expected. A significantly greater inter-assay accuracy and precision than these targets were observed (Table 9), with an inter-assay precision ranging from 4.0% to 8.5% and an inter-assay absolute accuracy ranging from 1.0% to 3.2%. Collectively, these results demonstrate that this method can achieve sufficient intra- and inter-assay accuracy and precision well within current industry targets. A dynamic range of this assay of 2,500-2.5 copies per &#181;L of PCR reaction can be defined based on these results, with an overall assay sensitivity of 2.5 copies per &#181;L of PCR reaction. As previously mentioned, it may be possible to validate wider dynamic ranges.
Next, it was necessary to evaluate assay accuracy and precision within the target matrix - in this case, tears. Typically, assays are validated prior to the initiation of clinical studies, meaning that tears collected from vector-treated patients are unlikely to be available for validation purposes. This can be artificially created by spiking the target AAV vector into tears collected from volunteer donors to create matrix-spiked QCs. Pooled human tears were collected by a third party (BioIVT). For proof of principle, an eGFP-expressing AAV2 vector acquired from a commercial source was utilized. The concentration of the AAV2 vector stock was empirically determined using ddPCR, without the use of a DNA isolation step, as described in this protocol. In each run, the AAV2 was independently spiked into the three tear aliquots at a high (expected 1.41 x 103 copies/&#181;L PCR reaction) and low (28.2 copies/&#181;L PCR reaction) level. Unspiked aliquots were included as a control to demonstrate the specificity of the method.
Intra-assay performance was assessed for each batch at each spike level. It was expected that all tear samples would have at least 10,000 droplets. This was met in 108 out of 108 wells tested across all six batches, with a mean total droplet number of 20,208 droplets/well (Table 10). Next, the inter-well %CV of each set of duplicate wells of each QC was expected to be &#8804;25.0% for the high and low spike levels. This was met in 36 out of 36 sets of wells tested across all six batches for the QCs, with a mean inter-well %CV of 3.2% (Table 11).
Within each batch, the intra-assay mean and standard deviation were calculated for each of the independently prepared tear spikes, and these were used to calculate an intra-assay mean for each concentration in each assay. This was used to assess the accuracy and precision of the assay in matrix (Table 12). We expected the intra-assay %CV to be &#8804;25.0% and high and low spike levels. This was met in six out of six batches for each level. Generally, greater intra-assay precision in matrix than the target could be achieved, with a mean intra-assay %CV of 3.7% at the high level and 12.2% at the low level (overall 8.0%). It was also expected the intra-assay %RE would be &#177;25.0% at both spike levels. This was met in six out of six batches for each level. Likewise, it was generally found that greater intra-assay accuracy in matrix than the target could be achieved, with a mean intra-assay absolute %RE of 8.1% at the low level and 11.3% at the high level (overall 9.7%). For the unspiked control, no eGFP signal was detectable in any of the aliquots (Table 12), demonstrating the specificity of the method in the human tear matrix.
Inter-assay accuracy and precision in tear matrix were also calculated using the intra-assay mean of each spike level within each batch. It was expected that the inter-assay precision would be &#8804;25.0% CV, and for inter-assay accuracy, we expected &#177;25.0% RE. A significantly greater inter-assay accuracy and precision than these targets were observed (Table 13), with an inter-assay precision of 5.5% at the high level and 7.1% at the low level, and with absolute inter-assay accuracy of 11.3% at the high level and 8.1% at the low level. Collectively, these results demonstrate the accuracy, precision, and specificity of the method in tear matrix.
Table 5: Quality controls used to define the dynamic range of the assay. Abbreviations: ULQC = upper limit quality control; HQC = high quality control; MQC = medium quality control; LQC = low quality control; LLQC = lower limit quality control; NTC = no template control. <a href="https://www.jove.com/files/ftp_upload/65495/Longacre Table 5.xlsx" target="_blank">Please click here to download this Table.</a>
Table 6: Total droplet counts and positive to total droplet ratios of synthetic double-stranded DNA quality control and NTC. Abbreviations: ULQC = upper limit quality control; HQC = high quality control; MQC = medium quality control; LQC = low quality control; LLQC = lower limit quality control; NTC = no template control. <a href="https://www.jove.com/files/ftp_upload/65495/Longacre Table 6.xlsx" target="_blank">Please click here to download this Table.</a>
Table 7: QC inter-well statistics (copy targets/&#181;L PCR reaction). Abbreviations: ULQC = upper limit quality control; HQC = high quality control; MQC = medium quality control; LQC = low quality control; LLQC = lower limit quality control; NTC = no template control. <a href="https://www.jove.com/files/ftp_upload/65495/Longacre Table 7.xlsx" target="_blank">Please click here to download this Table.</a>
Table 8: Intra-assay accuracy and precision of QCs (copy targets/&#181;L PCR reaction). Abbreviations: ULQC = upper limit quality control; HQC = high quality control; MQC = medium quality control; LQC = low quality control; LLQC = lower limit quality control; NTC = no template control. <a href="https://www.jove.com/files/ftp_upload/65495/Longacre Table 8.xlsx" target="_blank">Please click here to download this Table.</a>
Table 9: Inter-assay accuracy and precision of QCs (copy targets/&#181;L PCR reaction). Abbreviations: ULQC = upper limit quality control; HQC = high quality control; MQC = medium quality control; LQC = low quality control; LLQC = lower limit quality control; NTC = no template control. <a href="https://www.jove.com/files/ftp_upload/65495/65495_Longacre Table 9.xlsx" target="_blank">Please click here to download this Table.</a>
Table 10: Total droplet counts of tear samples. <a href="https://www.jove.com/files/ftp_upload/65495/Longacre Table 10.xlsx" target="_blank">Please click here to download this Table.</a>
Table 11: Tear sample inter-well statistics (copy targets/&#181;L PCR reaction). <a href="https://www.jove.com/files/ftp_upload/65495/Longacre Table 11.xlsx" target="_blank">Please click here to download this Table.</a>
Table 12: Intra-assay accuracy and precision of tear samples (copy targets/&#181;L PCR reaction). <a href="https://www.jove.com/files/ftp_upload/65495/Longacre Table 12.zip" target="_blank">Please click here to download this Table.</a>
Table 13: Inter-assay accuracy and precision of tear samples (copy targets/&#181;L PCR reaction). <a href="https://www.jove.com/files/ftp_upload/65495/65495_Longacre Table 13.xlsx" target="_blank">Please click here to download this Table.</a>
Supplementary Table S1: Sequences of primer, probes, and synthetic double-stranded DNA quality control utilized in this study. <a href="https://www.jove.com/files/ftp_upload/65495/65495_Longacre Supp. Table 1.xlsx" target="_blank">Please click here to download this Table.</a>

Watch this Scientific Journal Video about Addressing Regulatory Gaps in Molecular Studies by Quantifying Viral Vectors in Complex Matrices at JoVE.com

Here, we present a protocol for the development and validation of good laboratory practices in the compliant detection of adeno-associated viral vectors in human tears by droplet digital polymerase chain reaction in support of clinical development of gene therapy vectors.