ILM 50.5 July 2025

orderForm.title

orderForm.productCode

orderForm.description

orderForm.quantity

orderForm.itemPrice

orderForm.price

orderForm.totalPrice

orderForm.deliveryDetails.name

orderForm.deliveryDetails.accountNumber

orderForm.deliveryDetails.phone

orderForm.deliveryDetails.poNumber

orderForm.deliveryDetails.email

orderForm.deliveryDetails.companyName

orderForm.deliveryDetails.billingAddress

orderForm.deliveryDetails.deliveryAddress

orderForm.deliveryDetails.deliveryDetailsDeliveryAddressSameAsBillingAddress

orderForm.deliveryDetails.address1

orderForm.deliveryDetails.address2

orderForm.deliveryDetails.city

orderForm.deliveryDetails.state

orderForm.deliveryDetails.postCode

orderForm.deliveryDetails.country

orderForm.deliveryDetails.additionalInformation

orderForm.noItems

Sample Integrity Focus

How safe are your samples? Part III: Sample integrity through secure capping

Alexis MacLeod, Azenta Life Sciences, alexis.macleod@azenta.com

When using sample tubes, secure capping is paramount to protect sample integrity during the storage and handling process for a range of applications. These applications could include; Biobanking, Compound Management, Cell Therapy, Benchtop Research or applied industry.

Two major hazards that can be mitigated through safe and secure sample tube capping are:

• Evaporation • Cross contamination

Evaporation and Cross Contamination

Evaporation and cross contamination can occur either directly through the tube and cap or through a mechanical failure or fl aw. During long-term storage or handling, aqueous samples can evaporate or cross contaminate each other potentially causing irreplaceable samples to be lost or compromised, rendering them unusable for future research or treatment. In closed customer testing Azenta Sample Tubes have shown to provide higher sample integrity through lower levels of evaporation.

To ensure sample integrity, Azenta Sample Tubes have been leak tested and have been through rigorous testing methods both under vacuum (to test the mechanical seal of the tube and cap) and under pressure (to simulate an increase of internal tube pressure).

• The tubes are then placed on their sides in a tray lined with fi lter paper and placed in a vacuum chamber. A vacuum of -0.03Mpa (-19psi) is applied

• Tubes are left for 24 hours • The sample is re-weighed and the weight compared with the original recorded • Tubes and caps pass QC when there is no evidence of sample loss

Quality control processes ensure that every batch of Azenta Sample Tubes are above industry standard to provide safe and secure long-term storage for precious samples. If any of the tubes tested fail then the entire batch fails quality control and is inspected to mitigate any issues in future.

The rationale for these two tests is to maintain sample integrity during periods of increased internal pressure and to assure reliability of seal from the cap.

Internal vs. external thread

As aqueous samples expand when frozen, internal pressure is increased and burst pressure is paramount to calculate the safe working volume of each tube (see: How Safe Are Your Samples? Part II: Working Volume). When freezing samples, it is imperative to know the maximum fi ll volume of the tube being used as, when water- based samples are frozen, they expand by approximately 9%. This is an important factor when selecting an internal or external thread tube & cap, Figure 2 shows the results of comparative testing with 0.7ml Azenta sample tubes.

Figure 1: Azenta Life Sciences sample tubes undergo rigorous testing to ensure sample integrity. Under Pressure:

• Product samples are taken from each cavity of the tool, at the start, end, and during batch production

• The tube is connected to a silicone pressure tubing manifold via a hole drilled in the tube base

• The cap is applied with the minimum recommended torque for the tube and cap • The manifold is then attached to a test rig and a pressure of 2Bar is applied

• The pressure must be maintained for 10 seconds without any reduction in pressure observed.

Under Vacuum: • Product samples are taken from each cavity of the tool, at the start, end, and during batch production

• Tubes are fi lled with 0.15ml of with blue pigment. (Ethanol is used due to its low surface tension which will accelerate and exaggerate any leaks)

• The tubes are then capped, just below the minimum recommended torque level, and independently weighed

Figure 2: Graph showing the pressure generated with increasing fi ll volumes in both an internal and external thread 0.7ml sample storage tube

The results show that due to the higher headspace volume in the Azenta External Thread Sample Tube, the internal pressure is lower and therefore a greater volume of sample can be stored with a lower risk of sample loss through bursting when sealed with an external cap. Furthermore, results show that the Azenta External Thread Sample Tube offers more protection from evaporation.

INTERNATIONAL LABMATE - JULY 2025

Page 1 | Page 2 | Page 3 | Page 4 | Page 5 | Page 6 | Page 7 | Page 8 | Page 9 | Page 10 | Page 11 | Page 12 | Page 13 | Page 14 | Page 15 | Page 16 | Page 17 | Page 18 | Page 19 | Page 20 | Page 21 | Page 22 | Page 23 | Page 24 | Page 25 | Page 26 | Page 27 | Page 28 | Page 29 | Page 30 | Page 31 | Page 32 | Page 33 | Page 34 | Page 35 | Page 36 | Page 37 | Page 38 | Page 39 | Page 40 | Page 41 | Page 42 | Page 43 | Page 44 | Page 45 | Page 46 | Page 47 | Page 48 | Page 49 | Page 50 | Page 51 | Page 52