Estudo in vitro da ação de pentoxifilina em fibroblastos oriundos de cicatrizes hipertróficas pós-queimadura e de pele não-cicatricial / In vitro effects of pentoxifylline on human fibroblasts derived from post-burn hypertrophic scars and from normal skin

Isaac, Cesar

03 December 2007

Pentoxifilina (PTF), um derivado da metilxantina, tem ação terapêutica como agente antifibrótico. In vitro, a PTF causa inibição na produção de colágeno, glicosaminoglicanos e fibronectina, bem como promove acentuada redução na proliferação dos próprios fibroblastos de quelóides. A PTF na concentração de 1.000 g/mL foi seletiva no controle da inibição da síntese protéica pelos fibroblastos. O objetivo deste estudo foi verificar o comportamento in vitro de fibroblastos oriundos de cicatrizes hipertróficas (HSHF) e de pele não-cicatricial (NHF) na presença e ausência de PTF (1.000 g/mL), quanto à: proliferação celular, produção de colágeno e capacidade dos fibroblastos gerarem contração em modelo experimental de matriz de colágeno. Para tanto, foram utilizados fibroblastos cultivados a partir de amostras de cicatrizes hipertróficas e pele não-cicatricial doadas, com finalidade de pesquisa, pelo banco de Tecidos do Instituto Central do Hospital das Clínicas da FMUSP. Culturas celulares expostas a PTF apresentaram diminuição na proliferação celular em HSHF (46,35%) e em NHF (37,73%) (p<0,0001). Na presença de PTF, foi observada seletividade de inibição na síntese de colágenos, havendo inibição mais expressiva de colágeno tipo III em HSHF e de colágeno tipo I em NHF (p<0,0001). O modelo experimental de matriz de colágeno povoada por fibroblastos de cicatriz hipertrófica apresentou contração menor (12%) na presença de PTF (p<0,0001), em relação à sua ausência / Fibroblasts are thought to be partially responsible for the persisting contractile forces that result in burn contractures. Using a monolayer and fibroblast populated collagen lattice (FPCL) three-dimensional (3D) model we subjected hypertrophic scar and non-cicatricial fibroblasts to the antifibrogenic agent pentoxifylline (PTF) 1000g/mL attempting to reduce proliferation, collagen type I and III synthesis and contraction in this 3D model. Fibroblasts were isolated from post burn hypertrophic scars (HSHF) and non-scarred skin (NHF). Cells were grown in monolayer or incorporated into FPCL\'s and exposed to PTF. In monolayer, cell number proliferation was reduced (46.35% in HSHF group and 37.73% in NHF group) p<0,0001. The PTF also demonstrated to be selective on collagen type I and III synthesis inhibition suggesting higher inhibition of collagen type III on HSHF group and more evident inhibition of type I on NHF group. FPCL\'s containing PTF had surface areas reduced in about 12% p<0,0001. PTF showed inhibition effects on cell proliferation and reduced contraction in both HSHF and NHF

Cell culture

Cicatriz hipertrófica

Cultura celular

Fibroblastos

Fibroblasts

Hypertrophic scars

Matriz de colágeno

Pentoxifilina

Pentoxifylline

Estudo in vitro da ação de pentoxifilina em fibroblastos oriundos de cicatrizes hipertróficas pós-queimadura e de pele não-cicatricial / In vitro effects of pentoxifylline on human fibroblasts derived from post-burn hypertrophic scars and from normal skin

Cesar Isaac

03 December 2007

Pentoxifilina (PTF), um derivado da metilxantina, tem ação terapêutica como agente antifibrótico. In vitro, a PTF causa inibição na produção de colágeno, glicosaminoglicanos e fibronectina, bem como promove acentuada redução na proliferação dos próprios fibroblastos de quelóides. A PTF na concentração de 1.000 g/mL foi seletiva no controle da inibição da síntese protéica pelos fibroblastos. O objetivo deste estudo foi verificar o comportamento in vitro de fibroblastos oriundos de cicatrizes hipertróficas (HSHF) e de pele não-cicatricial (NHF) na presença e ausência de PTF (1.000 g/mL), quanto à: proliferação celular, produção de colágeno e capacidade dos fibroblastos gerarem contração em modelo experimental de matriz de colágeno. Para tanto, foram utilizados fibroblastos cultivados a partir de amostras de cicatrizes hipertróficas e pele não-cicatricial doadas, com finalidade de pesquisa, pelo banco de Tecidos do Instituto Central do Hospital das Clínicas da FMUSP. Culturas celulares expostas a PTF apresentaram diminuição na proliferação celular em HSHF (46,35%) e em NHF (37,73%) (p<0,0001). Na presença de PTF, foi observada seletividade de inibição na síntese de colágenos, havendo inibição mais expressiva de colágeno tipo III em HSHF e de colágeno tipo I em NHF (p<0,0001). O modelo experimental de matriz de colágeno povoada por fibroblastos de cicatriz hipertrófica apresentou contração menor (12%) na presença de PTF (p<0,0001), em relação à sua ausência / Fibroblasts are thought to be partially responsible for the persisting contractile forces that result in burn contractures. Using a monolayer and fibroblast populated collagen lattice (FPCL) three-dimensional (3D) model we subjected hypertrophic scar and non-cicatricial fibroblasts to the antifibrogenic agent pentoxifylline (PTF) 1000g/mL attempting to reduce proliferation, collagen type I and III synthesis and contraction in this 3D model. Fibroblasts were isolated from post burn hypertrophic scars (HSHF) and non-scarred skin (NHF). Cells were grown in monolayer or incorporated into FPCL\'s and exposed to PTF. In monolayer, cell number proliferation was reduced (46.35% in HSHF group and 37.73% in NHF group) p<0,0001. The PTF also demonstrated to be selective on collagen type I and III synthesis inhibition suggesting higher inhibition of collagen type III on HSHF group and more evident inhibition of type I on NHF group. FPCL\'s containing PTF had surface areas reduced in about 12% p<0,0001. PTF showed inhibition effects on cell proliferation and reduced contraction in both HSHF and NHF

Cicatriz hipertrófica

Cultura celular

Fibroblastos

Matriz de colágeno

Pentoxifilina

Cell culture

Fibroblasts

Hypertrophic scars

Pentoxifylline

A Comparative Analysis of the Biomechanics and Biochemistry of Cell-Derived and Cell-Remodeled Matrices: Implications for Wound Healing and Regenerative Medicine

Ahlfors, Jan-Eric Wilhelm

03 May 2004

The purpose of this research was to study the synthesis and remodeling of extracellular matrix (ECM) by fibroblasts with special emphasis on the culture environment (media composition and initial ECM composition) and the resulting mechanical integrity of the ECM. This was investigated by culturing fibroblasts for 3 weeks in a variety of culture conditions consisting of collagen gels, fibrin gels, or media permissive to the self-production of ECM (Cell-Derived Matrix), and quantifying the mechanics of the resulting ECM. The mechanical characteristics were related to the biochemistry of the resulting ECM, notably in terms of collagen accumulation and collagen fibril diameters. The ultimate tensile strength (UTS) of the collagen gels and fibrin gels at the end of the 3-week period was 168.5 ± 43.1 kPa and 133.2 ± 10.6 kPa, respectively. The ultimate tensile strength of the cell-derived matrices was 223.2 ± 9 kPa, and up to 697.1 ± 36.1 kPa when cultured in a chemically-defined medium that was developed for the rapid growth of matrix in a more defined environment. Normalizing the strength to collagen density resulted in a UTS / Collagen Density in these groups of 6.4 ± 1.9 kPa/mg/cm3, 25.9 ± 2.4 kPa/mg/cm3, 14.5 ± 1.1 kPa/mg/cm3, and 40.0 ± 1.9 kPa/mg/cm3, respectively. Cells were synthetically more active when they produced their own matrix than when they were placed within gels. The resulting matrix was also significantly stronger when it was self-produced than when the cells rearranged the matrix within gels that corresponded to a significantly larger fraction of non-acid and pepsin extractable collagen. These studies indicate that cell-derived matrices have potential both as in vitro wound healing models and as soft connective tissue substitutes.

tension

failure strain

mechanics

fibroblasts

regenerative medicine

serum-free

UTS

proteoglycans

thickness

glycosaminoglycans

extensibility

collagen

wound-healing model

cell-remodeled matrix

cell-derived matrix

fibroblast-populated

collagen gel

biomechanical characterization

fibrin gel

strength

chemically-defined medium

growth factors

tissue growth

tissue regeneration

total protein content

human

tissue formation

biochemical characterization

Extracellular matrix

Fibroblasts

Biomechanics

Biochemistry

Wound healing