versão On-line ISSN 1678-2674
Acta Cir. Bras. vol.26 no.6 São Paulo nov./dez. 2011
11 - ORIGINAL ARTICLE
Effect of laser on the remnant liver after the first 24 hours following 70% hepatectomy in rats1
Efeito do laser no fígado remanescente nas primeiras 24 horas após hepatectomia a 70% em ratos
Ailton Jose BarbosaI; Ana Carolina Delazia Albuquerque SantanaII; Tiago Castro e SilvaIII; Cristina KurachiIV; Natalia InadaIV; Vanderlei Salvador BagnatoV; Orlando de Castro e Silva JrVI
IPhD, Assistant Professor, Division of Digestive Surgery, Department of Surgery and Anatomy, FMRP-USP, Ribeirao Preto-SP, Brazil. Acquisition and interpretation of data
IIGraduate student, FMRP-USP, Ribeirao Preto-SP, Brazil. Responsible for manuscript writing, helped with technical procedures, collection and processing of study information
IIIFellow Master degree, Illinois Institute of Technology, Department of Applied Mathematics, Chicago, Illinois, USA. Statistical analysis, responsible for the English language
IVPhD, Assistant Professor, Department of Biophotonics, Institute of Physics of Sao Carlos, USP, Sao Carlos-SP, Brazil. Critical revision
VFull Professor, Institute of Physics of Sao Carlos, USP, Sao Carlos-SP, Brazil. Supervised all phases of the study
VIChairman and Head, Department of Surgery and Anatomy, FMRP-USP, Ribeirao Preto-SP, Brazil. Critical revision, supervised all phases of the study, responsible for manuscript writing
PURPOSE: To evaluate the mitochondrial function of the remnant liver (RL) in the early phase of liver regeneration in rats after 70% partial hepatectomy (PH).
METHODS: Sixty male Wistar rats (200-250g) submitted to 70% PH were divided into five groups according to the time of euthanasia and application or not of laser light: C = Control, time zero; 2 minutes, 4, 6 and 24 hours after PH. The dose of laser radiation was 22.5 J/cm2, wavelength of 660 nm (visible/red), in the remnant liver. We studied the respiration activated by ADP (state 3), basal mitochondrial respiration (state 4), respiratory control ratio (RCR) and mitochondrial membrane potential (MMP).
RESULTS: The mitochondrial function of RL changed at 4 and 6 hours after PH, with a significant increase in state 3 and a concomitant increase in state 4 and with maintenance of RCR. MMP differed significantly between the groups biostimulated with laser radiation and the control group 4 hours after HP, with a substantial reduction in the non-laser groups.
CONCLUSION: The laser light at the dose used in this study did not induce additional damage to the RL and seems to have delayed the hepatocellular metabolic overload of the remnant liver.
Keywords: Laser. Liver. Hepatectomy. Mitochondria. Liver Regeneration. Rats.
OBJETIVO: Avaliar a função mitocondrial do fígado remanescente (FR) na fase precoce da regeneração hepática em ratos após hepatectomia parcial (HP) a 70%.
MÉTODOS: Sessenta ratos machos Wistar (200 - 250g) submetidos à HP a 70%, foram distribuídos em cinco grupos de acordo com o tempo de eutanásia e com aplicação ou não de luz laser: C= Controle,tempo zero; 2 minutos, 4, 6 e 24 horas após HP. O laser foi utilizado na dose 22.5 J/cm2, 660 nm, no FR.Estudou-se o estado 3 (respiração ativada por ADP), estado 4 (respiração mitocondrial basal), razão de controle respiratório,estado 3/estado 4 (RCR) e o potencial de membrana mitocondrial(PMM).
RESULTADOS: A função mitocondrial do FR alterou-se no período de 4 e 6 horas após a HP com aumento significativo do estado 3 e aumento concomitante do estado 4, com manutenção da RCR. O PMM apresentou diferença significativa entre os grupos bioestimulados com laser e o controle a partir de 4 horas pós HP, com queda importante do grupo sem laser e tendência a equiparação dos valores após 24 horas.
CONCLUSÃO: A luz laser, na dose utilizada no presente estudo, não induziu lesão adicional ao FR e parece ter retardado a sobrecarga hepatocelular do fígado remanescente.
Descritores: Lasers. Fígado. Hepatectomia. Mitocôndria. Regeneração Hepática. Ratos.
After 70% partial hepatectomy (PH)1, proliferation of hepatocytes occurs almost synchronously throughout the tissue, whereas differentiated liver function is maintained to meet the demands of the organism. Since the animal's liver has about 8 x 107 cells, it can be concluded that a single hepatocyte has the clonogenic potential to produce 7 x 1012 livers, similar to the potential of hematopoietic progenitor cells. This finding is quite unexpected, given the high ploidy and the complexity of the functions performed by hepatocytes2.
Regeneration can be experimentally induced by any chemical, surgical or acute challenge which removes or destroys a large percentage of hepatic parenchyma. The tissue loss in the remnant liver (RL) rapidly triggers the regenerative process until the original weight is regained3. Concomitant with the regeneration, the RL reduced in size needs to keep its metabolic functions intact and adapt to the new hemodynamic conditions imposed by the new container/content relationship of the RL.
The liver regenerative process is recognized as a spectacular example of orderly and organized tissue growth controlled by multiple signals from cytokines and growth factors. There is complete restoration of liver mass, even after extensive acute cell damage, such as in toxic and viral fulminant hepatitis, after extensive surgical ablations, segmental resections due to large tumor masses and acute traumatic injuries, or after transplantation of liver segments3.
Although the term regeneration is commonly used, it is biologically incorrect, since the response induced by resection of liver tissue is not truly regenerative. The resected lobes do not grow again. The restoration of liver mass occurs by compensatory cellular hyperplasia in the remaining lobes, with a consequent increase in its dimensions. This suggests that liver growth is controlled by functional factors rather than anatomical factors. Whatever the nature of these factors, they seem to be quite accurate since the growth ceases when the liver reaches its original weight.
The process of liver regeneration is dependent on energy whose primary source is mitochondrial energy. After resection of the liver parenchyma, there is an increase of mitochondrial function in order to provide the RL with the energy required for the restoration of liver mass by hyperplasia and cellular hypertrophy. Therefore, the success of liver resection depends on the metabolic and regenerative capacity of the RL and is directly related to the continuous supply of energy produced by mitochondria4.
Additionally, the ability of laser light to interfere in the process of liver regeneration was demonstrated. In this experiment, there was an increase in hepatic mitotic and mitochondrial activities promoted by photobiostimulation which was assessed on the basis of oxidative phosphorylation and proliferating cell nuclear antigen5.
Thus, the purpose of the present study was to evaluate changes in mitochondrial function in the early phase of RL regeneration after 70% PH, and the effect of laser light on the hepatic mitochondria in this situation.
A total of 60 male Wistar rats weighing 200-250g were used. The animals were supplied by the Central Animal Facility of the Ribeirao Preto Campus, University of Sao Paulo, fed standard crow for laboratory rats (Purina Nutrimentos Ltda.) and receiving water ad libidum. The animals were kept in the Animal Facility of the Laboratory of Surgical Technique and Experimental Surgery, Department of Surgery and Anatomy, Faculty of Medicine of Ribeirao Preto, University of Sao Paulo, at room temperature, under a 12 hour light-dark cycle, in transparent polypropylene cages with a galvanized wire cover, measuring 41 x 34 x 16 cm, with a maximum population of five animals.
Animals were anesthetized with ethyl ether inhalation, kept in the supine position, and after PH of approximately 70% of the liver1, they were divided into 10 groups of six animals each (n=6), according to time of euthanasia (C=Control, 0 minutes, 2 minutes, 4, 6 and 24 hours), and according to whether or not the laser light was applied.
The RL was irradiated at 5 different points with red light helium neon laserwith a wavelength of 660 nm and power of 50 mW for a period of 30 seconds per point at a dose of 22.5 J/cm2 in each point, immediately after 70% PH. Later, after a pre-set period of time (C= 0', 2', 4 and 12 hours), the RL was collected and the animals were euthanized by exsanguination.
Samples of the resected liver were collected at the time of sacrifice for biochemical analysis of mitochondrial function respiration activated by ADP and basal mitochondrial respiration, respiratory control ratio (RCR) and membrane potential6.
Mitochondrial isolation and oxygen consumption
Isolation of liver mitochondria was performed by differential centrifugation7. Mitochondrial oxygen consumption was analyzed polarographically with a homemade oxygraph constructed at IFSC-USP equipped with a Clarck oxygen electrode, and the respiratory parameters were determined according to an established procedure. Succinate (5 mM) was used as oxidizable substrate in 1.4 ml of medium containing 125 mM sucrose, 65 mM KCl, 1 mM MgCl2, 2 mM KH2PO4, 0.1 mM EGTA, and 10 mM Hepes-KOH, pH 7.4; and 2 mg of mitochondrial protein were used. State 3 respiration was induced with 400 nmol MgADP, and state 4 respiration (basal mitochondrial respiration) was determined after phosphorylation of additional ADP8. The ratio between state 3 and state 4 rates (RCR), which represents coupling between electron transport and oxidative phosphorylation, was determined.
Electrical transmembrane potential difference (ΔΨ)
Electrical transmembrane potential difference (ΔΨ) was monitored spectroûuorimetrically by using 5 µM safranine-O as an indicator and an SLM-Aminco, Bowman, series 2, luminescence spectrophotometer at a 495/586 nm excitation/emission wavelength pair9. Assays were performed in an incubation medium containing 200 mM sucrose, 1 mM MgCl2, 2.5 mM NaH2PO4, and 10 mM Hepes-KOH at pH 7.4. Mitochondria were energized with 5 mM sodium succinate. The membrane potential variation was expressed as mV as usual.
Results of various groups were compared and analyzed using the non-parametric Wilcoxon-Mann-Whitney test, considering p<0.05 as the critical value for statistical significance.
In this study, we determined that the mitochondrial function of the RL changed, especially at 4 and 6 hours after PH, with a significant increase of respiration activated by ADP (state 3) and a concomitant increase in basal mitochondrial respiration (state 4), (Figure 1) and with maintenance of the RCR (Figure 2, panel A). Under the same conditions, there was a significant reduction in the electrical potential of the mitochondrial membrane (Figure 2, panel B), without significant evidence of mitochondrial swelling (data not shown).
We observed that 24 hours after PH the respiratory parameters (state 3, state 4 and RCR) returned to control levels (Figure 1, panels A and B and Figure 2, panel A). Regarding state 3, laser radiation led to a significant decrease in respiratory rate activated by ADP 4 hours, but not 6 hours after PH. Laser radiation did not alter the state 4 of mitochondrial respiration compared to control and, although reducing the levels of RCR 4 hours after PH, it did not cause mitochondrial uncoupling (Figures 1 and 2).
In the first two minutes, significant effects on mitochondrial bioenergetic function were not observed in the presence or absence of laser biostimulation. The most significant effects were observed 2 and 6 hours after PH in the presence and absence of laser radiation, returning to control levels 24 hours after PH.
After partial PH, the RL will be responsible for maintaining the life of the host. During the first hours and days after resection, it will undergo intense changes necessary to maintain its viability and therefore the maintenance of life of the host. Moreover, the greater the extent of parenchyma resected, the greater the adaptation of the RL to the new metabolic and hemodynamic conditions that occur due to the reduction of the hepatic parenchyma.
After PH, the RL goes into a state of metabolic overload10. Some authors indicate situations in which, after PH, the liver regeneration was significantly delayed by a resistance increased by a growth factor related to insulin by mechanisms mediated by oxidative stress10.
Due to reduction of the parenchyma, the RL must quickly adapt to the new hemodynamic conditions, keep its metabolism intact and still start the regeneration process. As mentioned earlier, the term regeneration is biologically incorrect. In fact what happens is intense hyperplasia and hypertrophy of RL parenchyma until it reaches its original weight, approximately one week after surgery in rats, when the regenerative process begins to decline until it stops around the 21st day.
Much of the increase of liver mass occurs three hours after PH and most of the liver mass is obtained within up to seven days. Several potential hepatocyte growth factors, such as HGF, TGFx and the anti-proliferative factor TGFb are identified early after PH. Likewise, it is known that more than 100 immediate-early genes which are activated by normally latent transcription factors in the transition between G0 and G1 show a significant action before the beginning of the new protein synthesis. It is also known that the peak of DNAsynthesis in hepatocytes occurs at about 24 hours while the peak of DNA in non-parenchymal cells occurs at about 36 to 48 hours after PH. It follows that the demand for energy needed for maintenance of hepatocellular function is increased in an RL already overburdened by its new anatomical and functional condition10.
In this study, we found that the mitochondrial changes in the RL that occurred in the first 24 hours after PH were detected mainly in the first six hours after PH. At four and six hours after PH, we observed a significant increase in cellular respiration activated by ADP, which is compatible with the highest energy requirement by the cell at this early stage of liver regeneration and hemodynamic adaptation of the RL. During this period there was a concomitant increase in basal mitochondrial respiration which suggested a trend to uncoupling oxidative phosphorylation, probably due to the metabolic overload that occurs in the RL. In this metabolic overload, due to the reduced or altered membrane potential, the cell membranes cannot meet the increased demand of the process of phosphorylation of ADP for ATD production. The use of laser light, which stabilized mitochondrial membranes, improved mitochondrial function with an increased rate of respiratory control, particularly six hours after PH.
In the state 4 respiration rate, laser radiation did not induce a change compared to the liver mitochondria that did not receive biostimulation (Figure 1, panel B). At four and six hours post-PH, the significant increase of this condition (state 4) was due mainly to the involvement of the opening of the mitochondrial permeability transition pore (MPTP), which facilitates the leakage of protons through the membrane, observed both by the increase in breathing at rest (state 4), and by the significant decrease in mitochondrial membrane potential (Figure 2, panel B). These two conditions were not altered by the action of a laser biostimulator because its effect is not able to regenerate and reverse the opening of pores in mitochondrial membranes. In future work, prior treatment of mitochondria isolated with the MPTP opening inhibitor, cyclosporin A, could be performed to corroborate the cited evidence obtained with specific antioxidants to evaluate the participation of the production of reactive oxygen species at the MPTP opening.
In previous work from our group, there was an increase of liver regeneration by laser light across the entire visible light spectrum analyzed5. Thus, the results of the present study suggest that there was a change of metabolic overload induced by laser light. This reduction in metabolic overload may determine the increase in liver regeneration observed in other studies.
These data reinforce the finding of other studies and suggest that metabolic overload of RL induced by hepatectomy per se, indicated in a sensitive way by mitochondrial alterations found in the first hours after hepatectomy11,12, is probably a consequence of an imbalance between energy supply and demand of the remnant liver13,14.
We can conclude that the remaining tissue depends on mitochondrial oxidative phosphorylation to meet the energy demand and defects indicative of a mitochondrial permeability transition have been reported in isolated mitochondria of RL after PH. With the hepatocellular adaptation, the mitochondrial changes found normalize over the hours after resection, when RL acquires a new metabolic status, evidenced by normalization of most mitochondrial parameters in a compensatory growth mechanism of RL15.
Measurements of cytosolic calcium ion concentration and reactive oxygen species are important and suitable for future work, since it is known that high levels of potassium promote oxidative stress of membrane thiol groups of NADPH, leading to the opening of the MPTP, which would explain both the increased rate of O2 consumption in state 4 and the significant decrease in mitochondrial membrane potential16.
Further analysis as a measure of ATP levels post-PH can support what has been observed here, i.e., a significant drop in the quantities of post-PH nucleotide, which is directly related to the early signs of mitochondrial oxidative stress in the process of liver regeneration 17.
Laser light(helium neon)at the dose used in this study, did not induce further damage to the RL and seemed to delay the hepatocellular metabolic overload of the liver remnant, measured by the set of mitochondrial alterations.
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Orlando Castro e Silva Junior
Rua Campos Salles, 890/92
15015-110 Ribeirão Preto-SP Brasil
Tel.: (55 19)3602-2242
Conflict of interest: none
Financial source: FAPESP
Presented at the XII National Congress on Experimental Surgery of the Brazilian Society for the Development of Research in Surgery-SOBRADPEC, 2011, October 26-29 Ribeirao Preto-SP, Brazil.
1 Research performed at Department of Surgery and Anatomy, Ribeirao Preto School of Medicine, University of Sao Paulo (FMRP-USP), Brazil.