This invention relates to apparatus for the transfer of biological material onto biological storage media, such as treated card or paper. The invention relates also to methods for transferring such materials onto the media.

It is known to transfer plant and like biological material onto treated storage card or paper for capturing biological information, for example when examining rare species in remote locations. Commercially available biological storage media is sold as a sample storage card and is supplied by GE Healthcare under the brand name FTA. This card is chemically treated to preserve DNA material. A known technique for transferring biological material onto the card involves vigorously rubbing the plant material onto the treated card in order to transfer cells from the plant onto the paper. The cells are generally lysed by the chemical treatment on the card and DNA material within the lysed cells becomes bound to the card. The DNA material can be sequenced later at a laboratory, without the need to further preserve the plant material, and without the need to store the card at low temperatures.

However, this technique is time consuming and laborious. Also, the risk of contaminating the collected DNA is high because manual steps are involved. Further, consistent transfer of material is very difficult because the manual steps are not always performed with the same degree of rubbing force or for the same length of time, which in turn leads to inconsistences in the quantity and quality of plant material transferred. Embodiments of the present invention address the above problems.

According to one aspect, the invention provides, apparatus for transferring biological material onto biological storage media, said apparatus comprising a powered hand held device including a powered hammer element, said apparatus further comprising an anvil portion and a storage media accepting area between the hammer and said anvil, the apparatus being operable such that in use the storage media is repeatedly compressed between the hammer and the anvil by the hammer. In an embodiment, the anvil is adjustable in position relative the hammer.

Conveniently, said adjustable relative position affords frictional holding of the storage media between the anvil and the hammer or a portion of the apparatus adjacent the hammer.

In an embodiment, the hammer includes a moving portion, having a repeatable path of powered motion, and a head portion generally in engagement with the storage media, and said compression is achieved by the striking of the head portion by the moving portion.

In an embodiment, the repeatable path of motion is reciprocating motion.

Preferably, the moving portion is powered to move at between 1 and 100 reciprocations per second, more preferably, about 60 reciprocations per second

In an embodiment the velocity of the moving portion is adjustable to vary the media compression force. In an embedment the anvil is detachable from the device, and more preferably, the device is a battery powered percussive tool including the hammer.

Conveniently, the tool includes a handle and an operating switch, and a head portion including the hammer, to which is fitted the anvil.

The invention can be put into effect in numerous ways. By way of example, embodiments are described below, with one example being illustrated in the drawings, wherein,

Figure 1 shows a side view of the embodiment; and

Figure 2 shows a cross sectional plan view of the embodiment. Referring to Figure 1 there is shown apparatus 10 which includes a commercially available device 100 known as an 'auto hammer' used conventionally for driving nails or pins. This device includes a head 1 10 and a handle 120 which houses batteries 130. An on-off switch 140 is used to operate the device 100. In operation, the device has a 5 hammer arrangement 150 which will reciprocate at around 60 impacts per second.

An additional, an anvil construction 20 has been added to the head 1 10 of the device 100. The anvil 20 sits snuggly on the head 1 10 and accepts biological samples storage media , in this case in the form of an FTA brand sample collecting card 200 in a slot 23. 10 The anvil further includes an adjustable anvil face 22, moveable by means of a thumb screw 24, to gently hold the card 200 in place between the anvil face 22 and its opposing face 25.

Referring additionally to Figure 2, there is shown a section through the apparatus 10 at 15 line ll-ll in Figure 1. The anvil 20 is shown in more detail having a post 26 which supports the thumbscrew 24, in turn supporting the anvil face 22. The card 200 is shown folded around a plant specimen 210 ready to be compressed. A possible mechanism for the auto hammer 100 is shown schematically. The mechanism includes a solenoid 160 for electrically driving a moving portion 152 in the direction of arrow A. This moving portion 20 152 is connected to an electrical switch 156 which disconnects as it moves forwards, so it is then forced in the opposite direction by a return spring 154. The solenoid reciprocates in the manner of a electric bell mechanism to repeatedly hit a hammer head 162, which in turn transmits a repeated compression force into the card 200 and plant sample 210, thereby crushing the plant material and causing plant cell material to transfer to the 25 sample card 200.

In practise, the mechanism works well by compressing the card and plant material at around 60 blows per second, although it is envisaged that slower reciprocations, for example 1 blow per second will yield good results, particularly for succulent plants, and 30 faster repetitions, for example 100 blows per second could be employed, particularly for dry plant material such as waxy leaves or dead plant material. In this case the reciprocating speed can be adjusted by altering the voltage applied to the solenoid, and/or by moving the contacts of the switch 156, and/or by adjusting the position of the return spring 154.

It is envisaged that the slot 23 illustrated is of sufficient dimensions to allow the card 200 to be moved relative to the hammer head 162, so that multiple sample attempts can be performed on one card. For example, the card could be moved so that one of 4 discrete locations on the card is compressed to provide four areas on the card where biological material is stored. Additionally, it can be seen that the card 200 is folded around the plant 210, which offers less chance of contaminating the plant material during the compression steps.

Experiments have shown a quicker transfer of plant material onto FTA cards compared with conventional manual transfer. A period of 1 to 10 seconds is enough to transfer sufficient material onto the card, with about 5 seconds being about right for most plant materials. Also the consistency of transfer is visually better than prior manual techniques.

Although one embodiment only has been illustrated, it will be apparent to the skilled addressee that modifications, variants, additions and omissions are possible within the scope and spirit of the invention defined herein.

For example, in the embodiment shown, an electrically powered solenoid type mechanism is shown, but other electrically powered means to produce a hammer impact are possible. For example, a rotary or rocking mechanism could be employed, providing a blow during rotation or pivoting. The rotary mechanism could be a cam driven by an electric motor and providing energy to drive the hammer. It is envisaged that the auto hammer or an alternative mechanism, are driven by electricity, preferably stored electricity from batteries, preferably rechargeable batteries.

Alternatively, other sources of power could be used, for example, pneumatic or hydraulic power could be employed. In the case of a pneumatic powered device, a compressed gas cylinder could be used to power a known pneumatic reciprocating mechanism, to provide the hammer blows needed to transfer the plant material to the cards. Such known pneumatic reciprocating mechanism are conventionally employed descaling tools and rivet guns.

In the embodiment shown, a separate auto hammer device and anvil arrangement are shown. However, where economic factors allow, a customised device could be produced incorporating the auto hammer device and the anvil as one moulding or one unit.

Whilst this invention has utility for collecting plant samples, it will be apparent that other biological samples could be collected too, for example biological material from insects or other animal specimens could be collected.