Fibrotic Venous Remodeling and Nonmaturation of Arteriovenous Fistulas

Laisel Martinez, Juan C Duque, Marwan Tabbara, Angela Paez, Guillermo Selman, Diana R Hernandez, Chad A Sundberg, Jason Chieh Sheng Tey, Yan-Ting Shiu, Alfred K Cheung, Michael Allon, Omaida C Velazquez, Loay H Salman, Roberto I Vazquez-Padron, Laisel Martinez, Juan C Duque, Marwan Tabbara, Angela Paez, Guillermo Selman, Diana R Hernandez, Chad A Sundberg, Jason Chieh Sheng Tey, Yan-Ting Shiu, Alfred K Cheung, Michael Allon, Omaida C Velazquez, Loay H Salman, Roberto I Vazquez-Padron

Abstract

The frequency of primary failure in arteriovenous fistulas (AVFs) remains unacceptably high. This lack of improvement is due in part to a poor understanding of the pathobiology underlying AVF nonmaturation. This observational study quantified the progression of three vascular features, medial fibrosis, intimal hyperplasia (IH), and collagen fiber organization, during early AVF remodeling and evaluated the associations thereof with AVF nonmaturation. We obtained venous samples from patients undergoing two-stage upper-arm AVF surgeries at a single center, including intraoperative veins at the first-stage access creation surgery and AVFs at the second-stage transposition procedure. Paired venous samples from both stages were used to evaluate change in these vascular features after anastomosis. Anatomic nonmaturation (AVF diameter never ≥6 mm) occurred in 39 of 161 (24%) patients. Neither preexisting fibrosis nor IH predicted AVF outcomes. Postoperative medial fibrosis associated with nonmaturation (odds ratio [OR], 1.55; 95% confidence interval [95% CI], 1.05 to 2.30; P=0.03, per 10% absolute increase in fibrosis), whereas postoperative IH only associated with failure in those individuals with medial fibrosis over the population's median value (OR, 2.63; 95% CI, 1.07 to 6.46; P=0.04, per increase of 1 in the intima/media ratio). Analysis of postoperative medial collagen organization revealed that circumferential alignment of fibers around the lumen associated with AVF nonmaturation (OR, 1.38; 95% CI, 1.03 to 1.84; P=0.03, per 10° increase in angle). This study demonstrates that excessive fibrotic remodeling of the vein after AVF creation is an important risk factor for nonmaturation and that high medial fibrosis determines the stenotic potential of IH.

Keywords: arteriovenous fistula; fibrosis; vascular access.

Copyright © 2018 by the American Society of Nephrology.

Figures

Graphical abstract
Graphical abstract
Figure 1.
Figure 1.
Surgeries, sample collection, and flow diagram of the study design. (A) Schematic representation illustrating the two surgical steps involved in creating a two-stage brachio-basilic AVF: (1) creation of the arteriovenous anastomosis (first-stage surgery), and (2) transposition of the remodeled AVF (second-stage surgery). The anatomic locations for the collection of native veins (first-stage) and AVF samples (second-stage) are shown. (B) Flow diagram indicating the sample collection algorithm, exclusion criteria, and subsequent histopathologic and statistical analyses. A total of 165 patients undergoing two-stage AVF creation were enrolled in the study. Native vein and AVF venous samples were obtained intraoperatively before the first-stage and second-stage procedures, respectively. If tissue sampling was not possible, the event was designated as vein or AVF unavailable.
Figure 2.
Figure 2.
Preexisting medial fibrosis is not associated with AVF nonmaturation. (A and B) Close-up photographs of Masson’s trichrome–stained cross-sections of native veins with (A) high and (B) low degree of medial fibrosis. Cells stain in red/pink, whereas collagen is shown in blue. Distances are in micrometers. I, intima; M, media. (C) Distribution of preexisting medial fibrosis in the first-stage veins cohort. (D) Probability of anatomic nonmaturation as predicted by preexisting medial fibrosis using logistic regression analysis. The black line represents the model, whereas gray lines indicate the upper and lower levels of the 95% CI.
Figure 3.
Figure 3.
Postoperative medial fibrosis predicts AVF nonmaturation. (A) Distribution of medial fibrosis in the second-stage AVFs cohort. (B) Probability of anatomic nonmaturation as predicted by postoperative medial fibrosis using logistic regression analysis. The black line represents the model, whereas gray lines indicate the upper and lower levels of the 95% CI. (C) Anatomic nonmaturation as predicted by postoperative medial fibrosis using a logistic regression model adjusted for sex. The combined nonlinear B coefficient (for both sexes) is shown in the graph.
Figure 4.
Figure 4.
Postoperative histology shows increased fibrosis in failed AVFs. Close-up photographs of Masson’s trichrome–stained cross-sections of AVFs with (A and B) anatomic nonmaturation and (C and D) successful maturation. Cells stain in red/pink, whereas collagen is shown in blue. Distances are in micrometers. I, intima; M, media.
Figure 5.
Figure 5.
Postoperative IH is associated with AVF nonmaturation in the presence of high medial fibrosis. (A and B) Probability of anatomic nonmaturation as predicted by postoperative IH (expressed as I/M area ratio) in AVFs with postoperative medial fibrosis (A) over and (B) under the median value in the second-stage AVFs cohort. (C) Probability of anatomic nonmaturation as predicted by the product of IH (expressed as I/M area ratio) and percent medial fibrosis (expressed as a decimal) in AVFs using logistic regression analysis. The black lines represent the models, whereas gray lines indicate the upper and lower levels of the 95% CIs.
Figure 6.
Figure 6.
Circumferential orientation of medial collagen fibers predicts AVF nonmaturation. (A) Angle of collagen fibers relative to the lumen, ranging from 0° (perpendicular to the lumen, radial direction) to 90° (circumferential direction). (B) Distribution of postoperative orientation angles in the second-stage AVFs cohort. (C and D) Probability of anatomic maturation failure as predicted by (C) the postoperative angle of medial collagen fibers and (D) the product of the postoperative angle and percent medial fibrosis (expressed as a decimal) using logistic regression analyses. The black lines represent the models, whereas gray lines indicate the upper and lower levels of the 95% CIs.

References

    1. Allon M, Robbin ML, Young CJ, Deierhoi MH, Goodman J, Hanaway M, Lockhart ME, Litovsky S: Preoperative venous intimal hyperplasia, postoperative arteriovenous fistula stenosis, and clinical fistula outcomes. Clin J Am Soc Nephrol 8: 1750–1755, 2013
    1. Tabbara M, Duque JC, Martinez L, Escobar LA, Wu W, Pan Y, Fernandez N, Velazquez OC, Jaimes EA, Salman LH, Vazquez-Padron RI: Pre-existing and postoperative intimal hyperplasia and arteriovenous fistula outcomes. Am J Kidney Dis 68: 455–464, 2016
    1. Allon M, Greene T, Dember LM, Vita JA, Cheung AK, Hamburg NM, Imrey PB, Kaufman JS, Robbin ML, Shiu YT, Terry CM, Umphrey HR, Feldman HI; Hemodialysis Fistula Maturation Study Group : Association between preoperative vascular function and postoperative arteriovenous fistula development. J Am Soc Nephrol 27: 3788–3795, 2016
    1. Castier Y, Brandes RP, Leseche G, Tedgui A, Lehoux S: p47phox-dependent NADPH oxidase regulates flow-induced vascular remodeling. Circ Res 97: 533–540, 2005
    1. Haas TL, Doyle JL, Distasi MR, Norton LE, Sheridan KM, Unthank JL: Involvement of MMPs in the outward remodeling of collateral mesenteric arteries. Am J Physiol Heart Circ Physiol 293: H2429–H2437, 2007
    1. Kucukguven A, Khalil RA: Matrix metalloproteinases as potential targets in the venous dilation associated with varicose veins. Curr Drug Targets 14: 287–324, 2013
    1. Tronc F, Mallat Z, Lehoux S, Wassef M, Esposito B, Tedgui A: Role of matrix metalloproteinases in blood flow-induced arterial enlargement: Interaction with NO. Arterioscler Thromb Vasc Biol 20: E120–E126, 2000
    1. Wong CY, Rothuizen TC, de Vries MR, Rabelink TJ, Hamming JF, van Zonneveld AJ, Quax PH, Rotmans JI: Elastin is a key regulator of outward remodeling in arteriovenous fistulas. Eur J Vasc Endovasc Surg 49: 480–486, 2015
    1. Hall MR, Yamamoto K, Protack CD, Tsuneki M, Kuwahara G, Assi R, Brownson KE, Bai H, Madri JA, Dardik A: Temporal regulation of venous extracellular matrix components during arteriovenous fistula maturation. J Vasc Access 16: 93–106, 2015
    1. Simone S, Loverre A, Cariello M, Divella C, Castellano G, Gesualdo L, Pertosa G, Grandaliano G: Arteriovenous fistula stenosis in hemodialysis patients is characterized by an increased adventitial fibrosis. J Nephrol 27: 555–562, 2014
    1. Wali MA, Eid RA, Dewan M, Al-Homrany MA: Pre-existing histopathological changes in the cephalic vein of renal failure patients before arterio-venous fistula (AVF) construction. Ann Thorac Cardiovasc Surg 12: 341–348, 2006
    1. Shiu YT, Litovsky SH, Cheung AK, Pike DB, Tey JC, Zhang Y, Young CJ, Robbin M, Hoyt K, Allon M: Preoperative vascular medial fibrosis and arteriovenous fistula development. Clin J Am Soc Nephrol 11: 1615–1623, 2016
    1. Harvey A, Montezano AC, Lopes RA, Rios F, Touyz RM: Vascular fibrosis in aging and hypertension: Molecular mechanisms and clinical implications. Can J Cardiol 32: 659–668, 2016
    1. Tsamis A, Krawiec JT, Vorp DA: Elastin and collagen fibre microstructure of the human aorta in ageing and disease: A review. J R Soc Interface 10: 20121004, 2013
    1. Wang R, Li H, Wan W, Gleason RL, Brewster LP: Collagen alignment correlates with differential biaxial stiffness in nonhuman primate carotid and femoral arteries. Arterioscler Thromb Vasc Biol 32: A351, 2012
    1. Allon M, Litovsky S, Young CJ, Deierhoi MH, Goodman J, Hanaway M, Lockhart ME, Robbin ML: Medial fibrosis, vascular calcification, intimal hyperplasia, and arteriovenous fistula maturation. Am J Kidney Dis 58: 437–443, 2011
    1. Asif A, Roy-Chaudhury P, Beathard GA: Early arteriovenous fistula failure: A logical proposal for when and how to intervene. Clin J Am Soc Nephrol 1: 332–339, 2006
    1. Robbin ML, Greene T, Cheung AK, Allon M, Berceli SA, Kaufman JS, Allen M, Imrey PB, Radeva MK, Shiu YT, Umphrey HR, Young CJ; Hemodialysis Fistula Maturation Study Group : Arteriovenous fistula development in the first 6 weeks after creation. Radiology 279: 620–629, 2016
    1. Ruiz-Ortega M, Rodríguez-Vita J, Sanchez-Lopez E, Carvajal G, Egido J: TGF-beta signaling in vascular fibrosis. Cardiovasc Res 74: 196–206, 2007
    1. Heine GH, Ulrich C, Sester U, Sester M, Köhler H, Girndt M: Transforming growth factor beta1 genotype polymorphisms determine AV fistula patency in hemodialysis patients. Kidney Int 64: 1101–1107, 2003
    1. Holzapfel GA: Collagen in arterial walls: Biomechanical aspects. In: Collagen: Structure and Mechanics, edited by Fratzl P, Heidelberg, Springer, 2008

Source: PubMed

Sponsorit ja yhteistyökumppanit

Sairaudet

Huumeiden interventiot

3
Tilaa