PERFUSABLE-TYPE DUAL PROXIMAL TUBULE CELL CONSTRUCT AND PRODUCING METHOD THEREOF FOR APPLYING IN VITRO ARTIFICIALRENAL TISSUE MODEL AND RENAL CELL THERAPY

20220072203

17/126449

December 18, 2020

The present disclosure is related to a perfusable-type bio-dual proximal tubule cell construct and a producing method thereof capable of applying an in vitro artificial organ model configured to include a first bioink comprising a decellularized substance derived from a mammalian kidney tissue and human umbilical vascular endothelial cells (HUVECs) and a second bioink comprising the decellularized substance and renal proximal tubular epithelial cells (RPTECs), wherein the first bioink and the second bioink are coaxial and printed in tubular constructs having different inner diameters. According to the present disclosure, it is possible to use the renal proximal tubule-on-a-chip as a bioreactor capable of observing a biological drug reaction similar to a real drug by perfusing various drugs to the renal proximal tubule-on-a-chip.

1. A perfusable-type bio-dual proximal tubule cell construct capable of applying an in vitro artificial organ model comprising: a first bioink comprising a decellularized substance derived from a mammalian kidney tissue and human umbilical vascular endothelial cells (HUVECs); and a second bioink comprising the decellularized substance and renal proximal tubular epithelial cells (RPTECs), wherein the first bioink and the second bioink are coaxial and printed in tubular constructs having different inner diameters.

2. The perfusable-type bio-dual proximal tubule cell construct of claim 1, wherein the first bioink is printed to configure a first tubular construct, the second bioink is printed to configure a second tubular construct, and at least a part of an outer surface of the first tubular construct is configured to be in contact with an inner surface of the second tubular construct.

3. The perfusable-type bio-dual proximal tubule cell construct of claim 2, wherein the first bioink and the second bioink are configured to include alginate so as to reduce a shape change after printing.

4. The perfusable-type bio-dual proximal tubule cell construct of claim 3, wherein the first bioink and the second bioink are configured to comprise the decellularized substance in a concentration of 20 mg/ml to 40 mg/ml and the alginate in a concentration of 5 mg/ml to 15 mg/ml.

5. The perfusable-type bio-dual proximal tubule cell construct of claim 4, wherein the decellularized substance is produced in the form of a hydrogel by lyophilizing the kidney tissue, treating the lyophilized kidney tissue with 0.3 M to 0.7 M of an acetic acid solution, and neutralizing the treated kidney tissue with 5 M to 15 M NaOH.

6. The perfusable-type bio-dual proximal tubule cell construct of claim 3, wherein the first tubular construct and the second tubular construct are simultaneously printed by a 3D printer provided with a coaxial double nozzle.

7. The perfusable-type bio-dual proximal tubule cell construct of claim 4, further comprising: a support configured to support the first tubular construct from the inner side of the first tubular construct and configured to be removed when the tubule cell construct is cultured.

8. The perfusable-type bio-dual proximal tubule cell construct of claim 7, wherein the support is printed on the inner side of the first tubular construct while being coaxial with the first tubular construct and the second tubular construct.

9. The perfusable-type bio-dual proximal tubule cell construct of claim 6, wherein the support is produced by printing support ink comprising Pluronic F127 (polyethylene oxide-b-polypropylene oxide-b-polyethylene oxide).

10. An renal proximal tubule-on-a-chip capable of applying an in vitro artificial organ model comprising: a vascular tubule construct which is printed with a first bioink comprising a decellularized substance derived from a mammalian kidney tissue and human umbilical vascular endothelial cells (HUVECs) and configured in a tubular shape; and a proximal tubule construct which is printed with a second bioink comprising the decellularized substance and renal proximal tubular epithelial cells (RPTECs) and configured in a tubular shape, wherein the vascular tubule construct and the proximal tubule construct are at least partially printed in parallel with each other and configured so that the outer surfaces thereof are in contact with each other.

11. The renal proximal tubule-on-a-chip of claim 10, further comprising: a case provided with a space in which the vascular tubule construct and the proximal tubule construct are printed.

12. The renal proximal tubule-on-a-chip of claim 11, wherein the case comprises: an artificial proximal tubule part configured to dispose a part of the vascular tubule construct and a part of the proximal tubule construct which are in contact with each other; and multiple fixing parts configured to fix both ends of the vascular tubule construct and both ends of the proximal tubule construct, respectively.

13. The renal proximal tubule-on-a-chip of claim 10, wherein the vascular tubule construct is printed by including a support that is coaxial with the first bioink and printed together on the inner side of the tubular part when the first bioink is printed, and is formed by removing the support after printing.

14. The renal proximal tubule-on-a-chip of claim 10, wherein the proximal tubule construct is printed by including a support that is coaxial with the second bioink and printed together on the inner side of the tubular part when the second bioink is printed, and is formed by removing the support after printing.

15. A producing method of a proximal tubule cell construct comprising the steps of: producing a decellularized substance derived from a mammalian kidney tissue; extracting and preparing human umbilical vascular endothelial cells (HUVECs) and renal proximal tubular epithelial cells (RPTECs) from a living kidney tissue; producing a first bioink comprising the decellularized material and the HUVECs; producing a second bioink comprising the decellularized material and the RPTECs; printing a vascular tubule construct using the first bioink; and printing a proximal tubule construct using the second bioink, wherein the printing of the vascular tubule construct and the printing of the proximal tubule construct are performed while the vascular tubule construct and the proximal tubule construct are at least partially in contact with each other.

16. The producing method of the proximal tubule cell construct of claim 15, wherein the printing of the vascular tubule construct and the printing of the proximal tubule construct are performed using a coaxial triple nozzle, and a support on a central side, the vascular tubule construct on the outer side of the support, and the proximal tubule construct on the outer side of the vascular tubule construct are simultaneously printed coaxially.

17. The producing method of the proximal tubule cell construct of claim 15, wherein the printing of the vascular tubule construct is performed using a coaxial double nozzle, and is performed by printing a support configured to support the vascular tubule construct from the inner side of the vascular tubule construct simultaneously with the vascular tubule construct.

18. The producing method of the proximal tubule cell construct of claim 17, wherein the printing of the proximal tubule construct is performed using a coaxial double nozzle, and is performed by printing a support configured to support the proximal tubule construct from the inner side of the proximal tubule construct simultaneously with the proximal tubule construct.

19. The producing method of the proximal tubule cell construct of claim 18, wherein the printing of the vascular tubule construct and the printing of the proximal tubule construct are performed while the vascular tubule construct and the proximal tubule construct are at least partially parallel to each other and the outer surfaces thereof are in contact with each other.

20. The producing method of the proximal tubule cell construct of claim 16, further comprising: removing the support.

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