Photothermal effects of laser tissue soldering.

Low-strength anastomoses and thermal damage of tissue are major concerns in laser tissue welding techniques where laser energy is used to induce thermal changes in the molecular structure of the tissues being joined, hence allowing them to bond together. Laser tissue soldering, on the other hand, is a bonding technique in which a protein solder is applied to the tissue surfaces to be joined, and laser energy is used to bond the solder to the tissue surfaces. The addition of protein solders to augment tissue repair procedures significantly reduces the problems of low strength and thermal damage associated with laser tissue welding techniques. Investigations were conducted to determine optimal solder and laser parameters for tissue repair in terms of tensile strength, temperature rise and damage and the microscopic nature of the bonds formed. An in vitro study was performed using an 808 nm diode laser in conjunction with indocyanine green (ICG)-doped albumin protein solders to repair bovine aorta specimens. Liquid and solid protein solders prepared from 25% and 60% bovine serum albumin (BSA), respectively, were compared. The efficacy of temperature feedback control in enhancing the soldering process was also investigated. Increasing the BSA concentration from 25% to 60% greatly increased the tensile strength of the repairs. A reduction in dye concentration from 2.5 mg ml(-1) to 0.25 mg ml(-1) was also found to result in an increase in tensile strength. Increasing the laser irradiance and thus surface temperature resulted in an increased severity of histological injury. Thermal denaturation of tissue collagen and necrosis of the intimal layer smooth muscle cells increased laterally and in depth with higher temperatures. The strongest repairs were produced with an irradiance of 6.4 W cm(-2) using a solid protein solder composed of 60% BSA and 0.25 mg ml(-1) ICG. Using this combination of laser and solder parameters, surface temperatures were observed to reach 85+/-5 degrees C with a maximum temperature difference through the 150 microm thick solder strips of about 15 degrees C. Histological examination of the repairs formed using these parameters showed negligible evidence of collateral thermal damage to the underlying tissue. Scanning electron microscopy suggested albumin intertwining within the tissue collagen matrix and subsequent fusion with the collagen as the mechanism for laser tissue soldering. The laser tissue soldering technique is shown to be an effective method for producing repairs with improved tensile strength and minimal collateral thermal damage over conventional laser tissue welding techniques.

[1]  J A Pearce,et al.  Rate process model for arterial tissue thermal damage: Implications on vessel photocoagulation , 1994, Lasers in surgery and medicine.

[2]  B. F. Matlaga,et al.  Microsurgical Anastomosis of Rat Carotid Arteries with the CO2 Laser , 1986, Plastic and reconstructive surgery.

[3]  S K Libutti,et al.  Comparison of laser-assisted fibrinogen-bonded and sutured canine arteriovenous anastomoses. , 1992, Surgery.

[4]  Ashley J. Welch,et al.  Importance of wound stabilization in early wound healing of laser skin welds , 1995, Photonics West.

[5]  G Godlewski,et al.  Morphologic changes in collagen fibers after 830 nm diode laser welding , 1997, Lasers in surgery and medicine.

[6]  J. Bailes,et al.  Aneurysm formation after low power carbon dioxide laser-assisted vascular anastomosis. , 1986, Neurosurgery.

[7]  C. Olsson,et al.  Laser tissue soldering in urinary tract reconstruction: first human experience. , 1995, Urology.

[8]  S. Thomsen,et al.  Laser-assisted microsurgical anastomosis. , 1986, Neurosurgery.

[9]  S. L. Griffith,et al.  Laser and suture anastomosis: Passive compliance and active force production , 1992, Lasers in surgery and medicine.

[10]  D. Poppas,et al.  Laser welding in urethral surgery: improved results with a protein solder. , 1988, The Journal of urology.

[11]  R. R. Krueger,et al.  Argon laser coagulation of blood for the anastomosis of small vessels , 1985 .

[12]  J. Terzis,et al.  Is Laser Nerve Repair Comparable to Microsuture Coaptation? , 1988, Journal of reconstructive microsurgery.

[13]  P. Howard,et al.  Skin flap closure by dermal laser soldering: a wound healing model for sutureless hypospadias repair. , 1997, Urology.

[14]  A. Moritz,et al.  Studies of Thermal Injury: II. The Relative Importance of Time and Surface Temperature in the Causation of Cutaneous Burns. , 1947, The American journal of pathology.

[15]  Michel Prudhomme,et al.  Applications and mechanisms of laser tissue welding in 1995: review , 1996, European Conference on Biomedical Optics.

[16]  Glenn M. LaMuraglia,et al.  Absorption characteristics at 1.9 μm: Effect on vascular welding , 1993 .

[17]  Rodney A. White,et al.  Crosslinking of extracellular matrix proteins: A preliminary report on a possible mechanism of argon laser welding , 1989, Lasers in surgery and medicine.

[18]  A J Welch,et al.  Optimal parameters for laser tissue soldering. Part I: Tensile strength and scanning electron microscopy analysis , 1999, Lasers in surgery and medicine.

[19]  W. Shaw,et al.  Laser-assisted venous anastomosis: a comparison study. , 1991, Journal of reconstructive microsurgery.

[20]  J. Cunningham,et al.  Enhancement of CO2 laser microvascular anastomoses by fibrin glue. , 1988, The Journal of surgical research.

[21]  B. Eppley,et al.  Facial nerve graft repair: suture versus laser-assisted anastomosis. , 1989, International journal of oral and maxillofacial surgery.

[22]  O H Frazier,et al.  Laser-assisted microvascular anastomoses: angiographic and anatomopathologic studies on growing microvascular anastomoses: preliminary report. , 1985, Surgery.

[23]  M. V. van Gemert,et al.  Laser tissue welding of dura mater and peripheral nerves: A scanning electron microscopy study , 1996, Lasers in surgery and medicine.

[24]  D. Poppas,et al.  Chromophore enhanced laser welding of canine ureters in vitro using a human protein solder: a preliminary step for laparoscopic tissue welding. , 1993, The Journal of urology.

[25]  A J Welch,et al.  Controlled temperature tissue fusion: Argon laser welding of canine intestine in vitro , 1996, Lasers in surgery and medicine.

[26]  T. Flotte,et al.  Dye‐enhanced laser welding for skin closure , 1992, Lasers in surgery and medicine.

[27]  G. L’italien,et al.  Laser assisted vascular welding with real time temperature control , 1996, Lasers in surgery and medicine.

[28]  G Godlewski,et al.  Scanning electron microscopy of microarterial anastomoses with a diode laser: comparison with conventional manual suture. , 1995, Journal of reconstructive microsurgery.

[29]  Scott A. Prahl,et al.  Welding artificial biomaterial with a pulsed diode laser and indocyanine green dye , 1995, Photonics West.

[30]  J. Seeger,et al.  Limited thrombogenicity of low temperature, laser‐welded vascular anastomoses , 1996, Lasers in surgery and medicine.

[31]  M C Oz,et al.  In vitro comparison of thulium‐holmium‐chromium:YAG and argon ion lasers for welding of biliary tissue , 1989, Lasers in surgery and medicine.

[32]  M R Treat,et al.  Laser tissue welding: A comprehensive review of current and future , 1995, Lasers in surgery and medicine.

[33]  Rodney A. White,et al.  Closure of rabbit ileum enterotomies with the argon and CO2 lasers: Bursting pressures and histology , 1988, Lasers in surgery and medicine.

[34]  W Gorisch,et al.  Repair of small blood vessels with the neodymium-YAG laser: a preliminary report. , 1979, Surgery.

[35]  G. Picó Thermodynamic aspects of the thermal stability of human serum albumin. , 1995, Biochemistry and molecular biology international.

[36]  D F Cikrit,et al.  CO2‐welded venous anastomosis: Enhancement of weld strength with heterologous fibrin glue , 1990, Lasers in surgery and medicine.

[37]  Rodney A. White,et al.  CO2 and argon laser vascular welding: Acute histologic and thermodynamic comparison , 1988, Lasers in surgery and medicine.

[39]  J. Dawes,et al.  Laser‐activated solid protein bands for peripheral nerve repair: An in vivo study , 1997, Lasers in surgery and medicine.

[40]  S Thomsen,et al.  Effect of blood bonding on bursting strength of laser‐assisted microvascular anastomoses , 1988, Microsurgery.

[41]  J. C. Vargas,et al.  Alteration of laser‐tissue interaction with the 805 nm diode laser using indocyanine green in the canine prostate , 1996, Lasers in surgery and medicine.

[42]  S K Libutti,et al.  Canine choledochotomy closure with diode laser-activated fibrinogen solder. , 1994, Surgery.

[43]  T. Yano,et al.  Comparison of laser vascular welding, interrupted sutures, and continuous sutures in growing vascular anastomoses , 1995, Lasers in surgery and medicine.

[44]  Massoud Motamedi,et al.  Laser-initiated decomposition products of indocyanine green (ICG) and carbon black sensitized biological tissues , 1997, Photonics West - Biomedical Optics.

[45]  Michael R. Treat,et al.  Welding of gallbladder tissue with a pulsed 2.15 μm thulium‐holmium‐chromium:YAG laser , 1989 .

[46]  P. Lawrence,et al.  A comparison of absorbable suture and argon laser welding for lateral repair of arteries. , 1991, Journal of vascular surgery.

[47]  Robert H. Ossoff,et al.  An Investigation of the Potential for Laser Nerve Welding , 1992, Otolaryngology--head and neck surgery : official journal of American Academy of Otolaryngology-Head and Neck Surgery.