Microsampling

Mediford Corporation has introduced microsampling for non-clinical toxicity studies taking into consideration the 3Rs of animal testing. Microsampling is a technique in which a small amount of blood is collected to measure drug concentrations. By using this technique, fewer animals are used than with conventional methods, and the amount of test substance required can be reduced, which is expected to result in total costs being lower.

What is Microsampling?

In recent years, animal welfare has been attracting worldwide attention. In the field of pharmaceutical development, there has been a concerted effort to adhere to the principles of 3Rs: Replacement (utilizing alternatives to animal use wherever possible), Reduction (minimizing the number of animals used), and Refinement (reducing pain and suffering to animals to the greatest extent possible). In addition, the FDA Modernization Act 2.0, a new law that eliminates the requirement for animal use in new drug development, has been enacted in the U.S., and it is expected that the number of animal procedures will be gradually reduced in the future. However, it is not clear whether all animal procedures can be eliminated.

A method that has been attracting attention is microsampling (MS), which involves collecting a very small amount of blood. This technique is defined by the ICH S3A Q&As and typically refers to blood collection volumes of 50 µL or less. One of the reasons for the introduction of MS in nonclinical toxicity assessment is the increased analytical sensitivity of instruments such as mass spectrometers. This advancement has made it possible to measure drug concentrations using smaller blood samples.

At present, in general toxicity studies using rodents in nonclinical studies, it is common to set satellite animals specifically for blood sampling in addition to the main test animals for toxicity evaluation. On the other hand, by using MS to collect samples from the main test animals for toxicokinetic (TK) evaluation, it becomes possible to analyze the relationship between toxicity evaluation values and TK values for each individual animal. This approach also contributes to 3Rs by reducing or eliminating the need for satellite animals and minimizing the amount of blood collected. Furthermore, by reducing the number of animals used, the amount of test substance required can be minimized, which is expected to lower development costs.

Advantages of Microsampling

Study design introducing Microsampling

As an example, this is a study design introducing microsampling (MS) to a rat 2-week repeated dose toxicity study. Typically, 5 males and 5 females are used in each toxicity evaluation group, and 4 males and 4 females are used in each TK satellite group. When MS is applied, blood is collected from the toxicity evaluation group, eliminating the need for animals in the TK satellite group. As a result, the amount of test substance used can be reduced by 44%.

Microsampling in a Rat 2-week Repeated Dose Toxicity Study

Dose	Conventional Method (using 72 animals)				Microsampling (using 40 animals)
	Main Group		TK Group		Main Group		TK Group
	Male	Female	Male	Female	Male	Female	Male	Female
0 mg/kg	5	5	4	4	5	5	0	0
100 mg/kg	5	5	4	4	5	5	0	0
300 mg/kg	5	5	4	4	5	5	0	0
1000 mg/kg	5	5	4	4	5	5	0	0

Required Amount of Test Substance^*　73g → 41g

*: Theoretical Value Excluding Loss
-44%

Toxicity assessment with Microsampling
<Case Study> Evaluation of azathioprine (immunosuppressant)

Methods

Six-week-old female Crl:CD(SD) rats were divided into two groups: the MS group, in which MS blood was drawn from the subclavian vein using microsampling, and the non-blood sampling group, in which no blood was drawn. Azathioprine (immunosuppressant) was administered orally to each group at doses of 0, 3, and 10 mg/kg/day for 4 weeks. Blood samples (50 µL/time point) were collected for TK measurement at 6 time points following the first administration and at 7 time points following the final administration. General condition observation, weight and food intake measurements, and urinalysis were performed during the administration period. On the day following the TK blood sampling, 24 hours after the final administration (Day 30), hematological test, blood biochemistry test, necropsy, organ weight measurement, and histopathological examination were performed. The results obtained were compared between the azathioprine group and the control group, and between the same dose in the MS and non-blood sampling groups. TK measurements were also performed using samples collected from the MS group at the first and final administrations.

Test article	Dose level (mg/kg)	Dose volume (mL/kg)	Dose conc. (mg/mL)	Number of animals
< Non-blood sampling group >
Control^*1	0	5	0	5
Azathioprine	3	5	0.6	5
Azathioprine	10	5	2	5
< Microsampling group >
Control^*1	0	5	0	5
Azathioprine	3	5	0.6	5
Azathioprine	10	5	2	5

*1: Control (0.5 w/v% MC)

Hematological test results

As effects of azathioprine administration, lower WBC, lymphocyte, eosinophil, and monocyte levels were observed in the MS and non-blood sampling groups. There was a statistically significant difference in erythrocyte system parameters (red circles in the figure below) in the MS group compared to the non-blood sampling group, but the values were within the range of the institutional background data. In other words, there were no apparent differences between the same dose in the MS and non-blood sampling groups.

Blood biochemistry test results

The effects of azathioprine administration were found to be similar between the MS and non-blood sampling groups. In addition, compared to the non-blood sampling group, there were statistically significant lower levels of total protein and albumin in the 10 mg/kg MS group, statistically significant lower levels of A/G and albumin and statistically significant higher level of α1 globulin in the 3 mg/kg group, and statistically significant higher level of calcium in the control group (green circles in the figure below), but these changes were within the range of institutional background data.

Pathological examination results

Effects of azathioprine administration included lower thymus weight, smaller thymus size, and decreased lymphocytes in the thymic cortex in the MS and non-blood sampling groups. There were no changes observed only in the MS group.

		Non-blood sampling group			MS group
Dose level (mg/kg)		0	3	10	0	3	10
Organ weight-body weight ratio
Thymus	(mg)	416.0	380.1	206.33^##	484.9	438.6	266.1^##
	(10^-3%)	190.93	175.44	97.08^##	224.17	199.26	129.89^#
Macroscopic Findings
Thymus	Small	0/5	0/5	3/5	0/5	0/5	3/5
Macroscopic Findings
Thymus	Decrease, Cortex, Lymphocyte	0/5	0/5	3/5	0/5	0/5	3/5

V.S. Control: #P<0.05, ##P<0.01

TK measurement results

Since azathioprine is rapidly metabolized in vivo to 6-mercaptopurine, we measured the concentration of the metabolite 6-mercaptopurine. Plasma 6-mercaptopurine concentrations increased in a dose-dependent manner and were not affected by repeated administration. Plasma samples collected via MS were suitable for an accurate TK measurement.

At first administration

At final administration

Conclusion

The effects of azathioprine administration were similar in hematology and blood biochemistry tests and pathological examination in the MS and non-blood sampling groups. Comparisons between the same doses in the MS and non-blood sampling groups showed no apparent differences. These results show that the use of MS for general toxicity studies in rats allows for an accurate assessment of the effects of azathioprine.

Frequently asked questions (FAQ)

Is it applicable to GLP studies?

A. Yes, it is applicable. There is no problem with the IND/NDA application since the method is listed in the ICH S3A Q&As.

We will be collecting blood samples from the toxicity evaluation group. Will this have any effect on the results?

A. There may be some fluctuations in red blood cell counts, etc., but since blood will also be collected from the control group, these fluctuations will not impact the comparison. Minor variations fall within the range of institutional background data and do not affect the toxicity evaluation.

Is there ever a shortage of sample volume?

A. From 50 µL of blood, 10 to 20 µL of plasma sample can be collected. TK measurement can be performed directly with this volume, but if necessary, the plasma sample may be diluted to secure the required sample volume for measurement. In such cases, additional TK validation will be conducted.

Is it possible to apply the method to studies using mice?

A. Mice have a low circulating blood volume and are easily affected by MS, making it difficult to apply. Therefore, it is primarily intended for use in toxicity studies in rats.

How much blood can be drawn from one animal?

A. Assuming that the circulating blood volume of rats is 64 mL/kg*, the total blood volume collected during a 24-hour period should be kept within 3% of the circulating blood volume to minimize the effect of MS.

*: Diehl et al., J Appl Toxicol. 2001

Would it be possible to explain how to collect blood using this method?

A. We would be happy to answer any individual inquiries. Please feel free to contact us directly.

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