This invention relates to a method of culturing cells and in particular to a method for culturing autogenous cells for preparing cultured epithelial autografts (CEA), as well as to a method of treating a mammalian patient by transplanting autogenous cells cultured by the method of the present invention, and in particular for treating burn victims.
The first Cultured Epithelial Autograft (CEA) was performed in Rheinwald and Green (Serial cultivation of strains of human epidermal keratinocytes: the formation of keratinizing colonies from single cells, Cell. 1975, 6:331-344). Since then skin grafts from cultured cells have been frequently used in treating skin defects such as burn wounds.
There are, however, some associated drawbacks which have not been fully addressed such as for example, fragile epidermal sheets and structural damage which may be sustained during transport of the grafts from a culture environment to the patient, poor “graft take”, microbiological contaminations etc.
Commercially available cultured epithelial autograft (CEA) products such as EPICEL have been put to good use in treating severely burned victims. A potential issue with commercially available products is that they make use of animal products which may not always be immunologically compatible with human patients. Products like EPICEL have overcome some of these compatibility issues, but at a huge expense making this product prohibitively expensive, especially in regions like Africa and other third world countries where patients struggle to afford basic health care treatment.
Where the commercial product is not readily available, it may be necessary to culture skin locally. The proximity of suitable laboratories to hospitals does not always make this a feasible option in the light of the practical concerns around the sterility and structural integrity during transport of such grafted cells. Barlow (U.S. Pat. No 6,039,972) describes a conformable wound dressing which is prepared by producing a sub-confluent layer of cultured epithelial cells anchored to the surface of a synthetic polymeric film which is hydrophobic, non-inhibitory to cell growth and non-cytotoxic. The film requires apertures, which are formed by perforations before or after cell culture. The growth of cells takes place in a generally used growth medium containing foetal calf serum.
Rennekampf et al. (Wound closure with human keratinocytes cultured on a polyurethane dressing overlaid on a cultured human dermal replacement, Surgery, 1996, 120:16-22) described the culturing of human keratinocyte (HK) sheets to a single layer on a polyurethane sheet, which is a synthetic hydrophilic dressing. The HK was obtained from human cadaveric donor skin and achieved a positive graft take in only 61% of the animals tested.
Van Dorp et al. (A modified culture system for epidermal cells for grafting purposes: an in vitro and in vivo study, Wound Repair Regen. 1999, 7(4):214-225) cultured human and porcine epidermal keratinocytes on polyester filler substrates. However, they found successful epithelium regeneration was only possible when the cell sheets were then detached from the substrate by enzyme treatment using Dispase. Enzymatic detachment using Dispase has been known to destroy certain cells which may be useful in the wound healing process.
Hernon et al. (Clinical experience using cultured epithelial autografts leads to an alternative methodology for transferring skin cells from the laboratory to the patient, Regenerative Med. 2006, 1(6):809-821) describe the use of a chemically defined surface for the culture of keratinocytes which could subsequently be transferred to the wound bed, without the need to enzymatically detach the cells from the surface. However, this method requires a fairly complex additional step of plasma polymerisation in which material containing acid groups are deposited onto a commercial medical grade polymer. The material is introduced in a gaseous phase and a plasma energy field is created by applying a voltage over a low vacuum field.
Atiyeh and Costagliola (Cultured Epithelial autograft (CEA) in burn treatment: Three decades later, Burns, 2007, 33:405-413) describe the use of new delivery systems to transfer keratinocytes, by growing the cells on a transplantable membrane, such as synthetic polymers, that can be transferred directly to the wound bed. The effects of these polymers on the quality of the cultured cells have, however, not been fully evaluated.
Chua et al. (In vitro evaluation of fibrin mat and Tegaderm™ wound dressing for the delivery of keratinocytes—Implications of their use to treat burns, Burns, 2008, 34:175-180) describes the use of Tegaderm™, a polyurethane based wound dressing, as a substrate for cell growth. The cells were grown on a feeder layer of irradiated 3T3-J2 cells in growth medium containing 10% fetal bovine serum and it was found that the cells grown on the Tegaderm™ show a weaker expression of some cells compared to cells grown on a fibrin mat, which provides a generally better environment for the cells.
De Corte et al. (Feeder layer- and animal product-free culture of neonatal foreskin keratinocytes: improved performance, usability, quality and safety, Cell Tissue Bank, 2012, 13:175-189) mention a silicone membrane delivery technology as a way of delivering subconfluent cells whilst also providing a wound cover.
Dahlquist (U.S. Pat. No. 8,658,851) and Iwamoto et al. (EP1 637 145) describe cells grown on flexible support comprising a hydrophobic polymer and uses cells derived from a subject that needs to be treated to avoid adverse immunological reactions.
Falk and lvarsson (Effect of a DACC dressing on the growth properties and proliferation rate of cultured fibroblasts, Journal of Wound Care, 2012, 21(7):327-332) studied the morphology and proliferation of human dermal fibroblasts using an experimental in vitro wound model. However, they used only commercially available fibroblasts and no other skin cell components like epidermal and dermal cells which would be required in a viable skin graft. They also made use of a growth medium containing 10% foetal calf serum.
Smith (US 2013/0072565) also makes use of hydrophobic substances such as dialkyl carbamoyl chloride (DACC) or alkyl ketene dimer (preferably associated with a carrier) to increase cell proliferation for growing commercially available human dermal fibroblasts using commercially available growth medium supplemented with 10% calf serum.
De Moraes et al. (Use of autologous fibrin glue in dermatologic surgery: application of skin graft and second intention healing, Rev Paul Med, 1998, 116(4):1747-1752) describe the production of fibrin glue (as a tissue adhesive in skin grafts) using a sample of autogenous blood.
Mishra (US Patent Application No. 2007/0122906) describes the use of a blood component such as platelet rich plasma (PRP) in a cell culture medium to grow and proliferate cells. However, the only support for the cells described, which serves to hold the cells together and direct development of mature tissue, is collagen which is generally extracted from tissue of young animals and may therefore result in immunological compatibility issues with a patient.
Scuderi et al. (Clinical application of autologous three-cellular cultured skin substitutes (CSS), in vivo, 2009, 23:991-1004) describe the use of a hyaluronic acid biomaterial scaffold on which human fibroblasts are grown, and in which the cultures media is enriched with, amongst other things, 10% of the patient's own blood serum. As the scaffold is derived from a biological source, there is also a rick of compatibility issues.
The preceding discussion of the background to the invention is intended only to facilitate an understanding of the present invention. It should be appreciated that the discussion is not an acknowledgment or admission that any of the material referred to was part of the common general knowledge in the art as at the priority date of the application.
In accordance with the first aspect of this invention there is provided a method of culturing autogenous cells for use in the treatment of a mammalian patient, the steps including:
Further features provide for substrate material to be used as a transfer dressing for transferring the cultured cells to the patient; and for the substrate material to be used as a wound cover dressing; for the substrate material to comprise a cellulose acetate, cotton gauze or nonwoven fabric; for the fatty acid to be dialkyl carbamoyl chloride (DACC), such as dihexadecyl-carbamoyl chloride or dioctadecyl-carbamoyl chloride, and/or alkyl ketene dimer (AKD); for the substrate material to be one of the CUTIMED SORBACT® range of products.
Further features provide for the cells to be skin cells or epithelial cells, for the cells to include fibroblasts and melanocytes.
Yet further features provide for the autogenous plasma to be obtained from a centrifuged blood sample of the patient and to be platelet rich plasma (PRP); and for the plasma to be applied regularly, preferably daily.
Still further features provide for the cells to be moisturised using a hydrogel, preferably every 2 to 4 days, and most preferably every 3 days.
The method may be further characterised in that no non-autogenous animal products are used in the process of growing the autogenous cultured cells and the cells cultured on the hydrophobic surface are relatively insensitive to non-sterile conditions.
According to a second aspect of this invention, there is provided a method of treating a mammalian patient by transplanting autogenous cells, cultured in vitro, including the steps of:
Further features provide for the autogenous cells to be skin cells, preferably epithelial cells, for the cells to include fibroblasts and melanocytes.
Yet further features provide for the autogenous plasma to be obtained from a centrifuged blood sample of the patient and to be platelet rich plasma (PRP); for the plasma to be applied regularly, preferably daily.
Still further features provide for the cells to be moisturised using a hydrogel, preferably every 2 to 4 days, and most preferably every 3 days.
According to a third aspect of this invention there is provided a kit for culturing autogenous cells for use in the treatment of a mammalian patient, the kit including:
Further features provide for the kit to contain a plurality of syringes for extracting plasma from a blood sample obtained from the patient; a plurality of sterile needles and 15/0 blades (theatre stock).
Yet further features provide for the kit to be in the form of a partitioned container with a plurality of zones; for a first zone to contain the trypsin solution or solution precursors, for a second zone to contain the substrate material and optionally a supporting frame for holding the substrate material in a flattened condition, for a third zone to contain the tubes, preferably acid-citrate-dextrose (ACD) tubes, and for a fourth zone to contain the syringes, sterile needles and blades and a tube of hydrogel; for each zone to be individually sealed by a peel away film cover.
The kit may further include a package insert containing instructions using the kit to culture autogenous cells, for example instructions for preparing the trypsin solution from the solution precursors, directions for applying the PRP to the cells placed on the substrate material and for moisturising the cells thereon using the hydrogel, and for applying the hydrophobic substrate containing a layer of cells thereon on a patient's wound.
According to a fourth aspect of this invention there is provided a system for culturing autogenous cells for use in the treatment of a mammalian patient, the system including:
A further feature provides for the applicator unit to include a robotic arm operable to select a dosage unit associated with the patient, the dosage unit containing the autogenous plasma obtained from a blood sample of the patient, and for the applicator unit to apply the autogenous plasma contained in the selected dosage unit.
Further features provide for the system to include a dosage unit bank including a plurality of dosage unit zones each of which being configured to hold a dosage unit, each dosage unit zone being associated with a patient, for the identifying component to be operable to identify a dosage unit zone associated with the patient and for the robotic arm to be operable to select and extract a dosage unit from the identified dosage unit zone.
A further feature provides for the system to include a plurality of dosage units, each of which including an outlet and a plunger, and for the robotic arm to be operable to position the outlet proximate the substrate zone associated with the patient and to urge the plunger towards the outlet to operatively apply autogenous plasma contained therein to cells on a substrate material contained within the substrate zone. The dosage unit may be an acid-citrate-dextrose (ACD) dosage unit.
A further feature provides for the identifying component to maintain a look-up table in which each substrate zone is associated with coordinates and with a patient, and for the identifying component to include a tracking component to track the position of the applicator unit relative to the coordinates of each substrate zone, and for the identifying component to identify the patient associated with a substrate zone by comparing the position of the applicator unit to the coordinates of the substrate zones stored in the look-up table so as to identify the substrate zone to which the applicator unit is proximate and to thereby to identify the patient associated with the substrate zone.
A further feature provides for the identifying component to maintain a look-up table in which each dosage unit zone is associated with coordinates and with a patient, and for the tracking component to track the position of the applicator unit relative to the coordinates of each dosage unit zone, and for the identifying component to identify the dosage unit zone associated with the patient by comparing the position of the applicator unit to the coordinates of the dosage unit zones stored in the look-up table so as to identify the dosage unit zone to which the applicator unit is proximate and to thereby to identify the dosage unit zone associated with the patient.
A further feature provides for the incubator to be temperature controlled, and for a temperature selected from the range of 30 degrees Celsius to 38 degrees Celsius to be maintained, preferably 37 degrees Celsius.
Aspects of the invention will now described, by way of example only, with reference to the accompanying drawings.
In the drawings:
A method of culturing autogenous cells as well as a method of treating a mammalian patient is described. The cells are cultured on a substrate material having a surface treated with a fatty acid ester so as to have a strong hydrophobic surface and autogenous plasma obtained from a blood sample of the patient is used as a growth medium in order to culture the cells. The substrate material is also used as a transfer dressing for transferring the cultured cells to the patient and as a wound cover dressing. A kit as well as a system for culturing autogenous cells using the culture method is also described.
The cells were grown on a low cost hydrophobic substrate material, in this embodiment the hydrophobic dressing known as CUTIMED SORBACT®, which served as a growth template for epithelial cells and well as a transfer medium and a wound cover dressing.
Animal products, such as bovine plasma which is commonly used as growth medium for culturing cells, were not used in the culturing process of the present invention. Instead a patient's autogenous plasma, extracted from a blood sample of the patient, was used as a growth medium to feed the cells daily. The cells were also shown to proliferate equally well in sterile and in non-sterile conditions.
Aspects of the invention will now be described in more detail with reference to the following non-limiting examples.
Materials
Equipment:
Biological requirements:
Method
The incubator was cleaned with a chlorhexidine solution and an alcohol solution and sterile gauze with sterile water and set to warm up to 36.8 degrees Celsius. The target temperature was 37 degrees Celsius.
A skin biopsy was transported from theatre to laboratory in a sterile specimen container, immediately after an operation to remove the skin was performed. With loupes on and using the scalpel with a number 15/0 blade, the epidermis and dermis was cut off and separated. Small fragments of epithelium were cut smaller. Some keratinocytes were scraped off without using loupes.
Boiling water was used to sterilise two specimen bottles which were used to mix Trypsin powder in sterile water. The small fragments of epithelial skin were then placed in the sterile specimen bottles with the trypsin solution to further separate the epidermal and dermal elements.
A RECELL kit was also sterilised with boiling water and used to assist in cell preparation. A small sift in the kit was used to rinse off the trypsin, and forceps were then used to pick up minute specks of epithelial cells and place them on six hydrophobic CUTIMED SORBACT® pads in the central area of the pads. Other cells were placed in the two sterilised specimen bottles.
Six tubes of blood with 6 ml in each were then centrifuged at 3500 revolutions per minutes (rpm) for 8 minutes. Thereafter the tops of the tubes were removed and the plasma was drawn up with a sterile 20 ml syringe and 18-gauge needle. Meticulous attention was given to avoiding drawing up any red blood cells which might contain pyrogenic cytokines which are pro-inflammatory, like Interleukin-1, 6 and tumour necrosis factor-alpha (TNF-alpha).
The plasma was sprayed onto the cells on the CUTIMED SORBACT® pads and into the specimen bottles containing cells. CUTIMED SORBACT® ribbon gauze was laid down between the pads to form a border for the cell growth and to avoid the cells from growing over the edges of the pads.
The cells were nourished daily with fresh PRP. Moistness in the incubator was maintained by adding sterile water to the water inlet on the outside of the incubator on a daily basis. Intrasite gel was applied with a sterile glove over the cultured epithelial autograft (CEA) every third day to prevent the cells from drying out too much.
On day 14 of the CEA growth, the target day for cell transplantation was reached, exactly 108 days after the patient's admission.
The incubator with the cultured cells was taken to theatre and the cells kept at 37 degrees Celsius. After anaesthesia commencement, 36 ml of blood for PRP was taken from the patient's A-line. The patient was washed with chlorhexidine soap and draped with sterile clothes. Wound debridement was done by gentle scraping of raw areas with a metal ruler's blunt side/tip. This was done over previously grafted xenograft areas as well as a donor site on the left medial lower leg. Haemostasis was obtained with swabs soaked in an adrenalin solution (Ringers Lactate 1 litre and 1 ampule of adrenaline and 800 mg Lignocaine). CUTIMED SORBACT® pads with the CEA were then transplanted directly onto the wounds of the back, left arm, left thigh and knee with the simultaneous application of PRP. On the patient's right arm, thigh and leg, CUTIMED SORBACT® pads were used with squirted CEA and fresh PRP. A sacral bedsore was also treated with squirted CEA from cells grown in the two sterile specimen bottles, with autogenous PRP on CUTIMED SORBACT®pads. The back dressing were fixed with IOBAN, an iodine containing film dressing. The rest of the dressings were bandaged with cling/crepe.
Results:
A 78.16% graft take was achieved. The CEA included cells grown from deeper skin layers (not just epithelial cells as in the classic technique, but including fibroblasts and melanocytes).
Plasma Dilution Studies
Results of Plasma Dilution Studies
Cell Types
Comparative Dressing Study
Dried out dressings: 3-4 months after CEA±3-4 days of Feeds.
Findings:
Another aspect of the invention extends to a portable kit (1) for culturing autogenous cells for use in the treatment of a mammalian patient, as illustrated in one embodiment shown in
Each zone of the partitioned container (2) is individually sealed by a peel away film cover.
The Trypsin solution in the first zone (3) is used for separating epidermal and dermal cells of a biopsy obtained from a patient, as per the set of instructions contained in the fourth zone (6). The cells can be mixed with the solution directly in the first zone and the cells for culturing picked out of the zone (3) and placed onto the hydrophobic substrate material in the second zone (4).
Once a blood sample from a patient has been centrifuged and the PRP extracted, using syringes from the fourth zone (6), the plasma is placed in the ACD tubes, and can then be applied onto the cells as a growth medium on a daily basis. Application of the plasma can be performed according to set of instructions included in the fourth zone (6).
The instructions also include steps for moisturising the cells growing on the substrate material using the hydrogel, and for applying the hydrophobic substrate containing a layer of cells thereon onto a patient's wound.
Another aspect of the present invention extends to a system (100) for culturing autogenous cells for use in the treatment of a mammalian patient, one exemplary embodiment of which is illustrated in
The system (100) includes an incubator (110) having a plurality of substrate zones (112). Each zone (112) is configured to receive a substrate material (114) having cells obtained from a patient placed thereon. Placing cells of a patient on the substrate material (114) enables autogenous cells to be cultured thereon. The incubator (110) is temperature controlled such that a temperature selected from the range of 30 degrees Celsius to 38 degrees Celsius, and preferably 37 degrees Celsius, is maintained.
The system (100) also includes a dosage unit bank (120) which includes a plurality of dosage unit zones (122). Each dosage unit zone (122) is configured to hold a dosage unit (124) which is associated with a patient. Each dosage unit (124) includes a tubular body having an outlet at a first end thereof and a plunger at a second end thereof. A chamber is defined between the plunger and the outlet and contains autogenous plasma of the patient with which the dosage unit (124) is associated. In some embodiments, the dosage unit may be an acid-citrate-dextrose (ACD) dosage unit.
The system (100) includes an identifying component (130) which maintains a look-up table in which each substrate zone (112) is logically associated with coordinates (e.g. x-, y- and z-coordinates) and with a patient (e.g. a patient identifier such a patient name or patient number). In this manner, each substrate zone (112) is associated with a patient.
The identifying component (130) is operable to identify a patient associated with the substrate zone (112) or to identify a substrate zone (112) associated with a patient. In this embodiment, the identifying component (130) includes a tracking component (132) to track the position of the applicator unit (106) relative to stored coordinates of each substrate zone (112). The identifying component (130) identifies the patient associated with a substrate zone (112) by comparing the position of the applicator unit (106) to the coordinates of the substrate zones stored in the look-up table so as to identify the substrate zone to which the applicator unit (106) is proximate and to thereby identify the patient associated with the substrate zone (112).
The identifying component (130) further maintains a look-up table in which each dosage unit zone (122) is logically associated with coordinates (e.g. x-, y- and z-coordinates) and with a patient. In this manner, each dosage unit zone (122) is associated with a patient.
The identifying component (130) is operable to identify a dosage unit zone (122) associated with the patient. The tracking component (132) is operable to track the position of the applicator unit (106) relative to the coordinates of each dosage unit zone (122). The identifying component (130) is operable to identify the dosage unit zone (122) associated with the patient by comparing the position of the applicator unit (106) to the coordinates of the dosage unit zones (122) stored in the look-up table so as to identify the dosage unit zone (122) to which the applicator unit (106) is proximate and to thereby to identify the dosage unit zone associated (122) with the patient.
The applicator unit (106) includes a robotic arm (108) having an end effector (109) which is operable to select and extract a dosage unit (124) associated with a particular patient from the dosage unit zone (122) in which it is located and to apply autogenous plasma of the patient contained therein to cells on the substrate material (114) contained in the substrate zone (112) which is associated with the patient.
In use, a particular patient may be identified. The robotic arm (108) identifies a dosage unit zone (122) which is associated with the patient. The end effector (109) removes the dosage unit (124) from the identified dosage unit zone (122). The substrate zone (112) associated with the patient is then identified and the dosage unit (124) is positioned proximate the substrate material (114) located within the substrate zone (112) and having cells obtained from the patient placed thereon. The end effector (109) urges the plunger of the dosage unit (124) towards the outlet to apply the autogenous plasma contained therein to the cells placed on a substrate material (114). The autogenous plasma, when applied to the cells on the substrate material (114) acts as a growth medium in order to culture cells.
The system (100) is configured to operate autonomously such that cells for a number of patients may be cultured on a large scale and with minimal human intervention. For example, the applicator unit may run autonomously to apply autogenous plasma of a plurality of patients to their corresponding one or more substrate materials contained within the incubator so as to culture cells on a large and ongoing scale, for example for the duration that a patient is at a facility for treatment.
It should be appreciated that the embodiment of the system described above is exemplary and that various alterations and modifications may be made thereto. For example, in another embodiment, each substrate zone and dosage unit zone may have a computer-and/or human-readable identifier or indicia (e.g. a label and/or barcode) disposed thereon. The identifier may be usable by the identifying component to identify a patient associated with each of the substrate zones and dosage unit zones.
The hydrophobic dressing used for cell grafting in the present invention, CUTIMED SORBACT® which has a hydrophobic coating made from DACC, is capable of reducing the effects of shear stress, metabolic stress and tissue infection. The DACC attracts hydrophobic bacteria and renders them inert. The Applicant postulated and found that the hydrophobic action of CUTIMED SORBACT® would allow plasma, in the form of PRP, to be applied to the substrate and the cells could grow within the plasma droplets. Dressings of this type are further described in U.S. Pat. No. 4,617,326 and US patent application no. 2006/012980, which are incorporated herein by reference.
The applicant envisages that the methods and materials of the invention are particularly beneficial in avoiding infection due to the combined anti-infective effects of the hydrophobic CUTIMED SORBACT® dressing and the use of autogenous plasma. The applicant postulates that the use of autogenous plasma allows the anti-infective effects of any antibiotic treatment, tailored specifically to the patient's bacterial profile, to persist during the in vitro culturing process.
Throughout the specification and claims unless the contents requires otherwise the word ‘comprise’ or variations such as ‘comprises’ or ‘comprising’ will be understood to imply the inclusion of a stated integer or group of integers but not the exclusion of any other integer or group of integers.
Filing Document | Filing Date | Country | Kind |
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PCT/IB2015/057070 | 9/15/2015 | WO | 00 |