The anatomy of the corrugator supercilii muscle: part II. Supraorbital nerve branching patterns.

BACKGROUND: This article focuses on delineation of supraorbital nerve branching patterns relative to the corrugator muscle fibers and identifies four branching patterns that help improve understanding of the local anatomy. METHODS: Twenty-five fresh cadaver heads (50 corrugator supercilii muscles and 50 supraorbital nerves) were dissected and the corrugator supercilii muscles isolated. After corrugator supercilii muscle measurement points were recorded for part I of the study, the supraorbital nerve branches were then traced from their emergence points from the orbit and dissected out to the defined topographical boundaries of the muscle. Nerve branching patterns relative to the muscle fibers were analyzed, and a classification system for branching patterns relative to the muscle was created. RESULTS: Four types of supraorbital nerve branching patterns were found. In type I (40 percent), only the deep supraorbital nerve division sent branches that coursed directly along the undersurface of the muscle. In type II (34 percent), branches emerging directly from the superficial supraorbital nerve were found in addition to the branches from the deep division. Type III (4 percent) included discrete branches from the superficial division, but none from the deep division. In type IV (22 percent), significant branching began more cephalad relative to the muscle and, therefore, displayed no specific relation to the muscle fibers. CONCLUSIONS: Contrary to previous reports, both the deep and superficial divisions of the supraorbital nerve are intimately associated with corrugator supercilii muscle fibers. Four supraorbital nerve branching patterns from these divisions were found. Potential sites of supraorbital nerve compression were identified. This more detailed anatomical information may improve the safety and accuracy of performing complete corrugator supercilii muscle resection.

Anatomy of the corrugator supercilii muscle: part I. Corrugator topography.

BACKGROUND: Complete corrugator supercilii muscle resection is important for the surgical treatment of migraine headaches and may help prevent postoperative abnormalities in surgical forehead rejuvenation. Specific topographic analysis of corrugator supercilii muscle dimensions and its detailed association with the supraorbital nerve branching patterns has not been thoroughly delineated. Part I of this two-part study aims to define corrugator supercilii muscle topography with respect to external bony landmarks. METHODS: Twenty-five fresh cadaver heads (50 corrugator supercilii muscles and 50 supraorbital nerves) were dissected to isolate the corrugator supercilii muscle from surrounding muscles. Standardized measurements of corrugator supercilii muscle dimensions were taken with respect to the nasion and lateral orbital rim. RESULTS: Relative to the nasion, the most medial origin of the corrugator supercilii muscle was found at 2.9 +/- 1.0 mm; the most lateral origin point, 14.0 +/- 2.8 mm. The lateralmost insertion of the corrugator supercilii muscle measured 43.3 +/- 2.9 mm from the nasion or 7.6 +/- 2.7 mm medial to the lateral orbital rim. The most cephalic extent (apex) of the muscle was located 32.6 +/- 3.1 mm cephalad to the nasion-lateral orbital rim plane and 18.0 +/- 3.7 mm medial to the lateral orbital rim. There were no statistical differences noted between the right and left sides. CONCLUSIONS: The dimensions of the corrugator supercilii muscle are more extensive than previously described and can be easily delineated using fixed bony landmarks. These data may prove beneficial in performing safe, complete, and symmetric corrugator supercilii muscle resection for forehead rejuvenation and for effective decompression of the supraorbital nerve and supratrochlear nerve branches in the surgical treatment of migraine headaches.

Fluid resuscitation in liposuction: a retrospective review of 89 consecutive patients.

BACKGROUND: In 1998, the senior author presented the intraoperative fluid ratio, defined as the volume of super-wet solution and intraoperative intravenous fluid divided by the aspiration volume, to guide resuscitation fluid volumes in super-wet liposuction. The senior author demonstrated that intraoperative fluid ratios of 2.1 for small-volume and 1.4 for large-volume liposuction were safe and did not cause volume overload sequelae. A high urine output was common and reflected a mild overresuscitation, which could have adverse consequences in patients with undiagnosed cardiopulmonary disease. The purpose of this study was to compare overresuscitation sequelae in a cohort of consecutive super-wet liposuction patients using a new fluid management formula in which replacement fluid was given after 5000 cc of lipoaspirate instead of 4000 cc, as initially described. METHODS: The charts of 89 consecutive patients undergoing super-wet liposuction were retrospectively reviewed. RESULTS: The intraoperative fluid ratio was 1.8 for the small-volume reductions (< 5000 cc, n = 68) and 1.2 (> 5001 cc, n = 21) for the large-volume reductions. There were no episodes of pulmonary edema, congestive heart failure exacerbation, or other major complications. The average urine output in the operating room, the recovery room, and while on the floor was 1.5, 1.6, and 2.9 cc/kg/hour for the small-volume group and 1.7, 1.8, and 2.5 cc/kg/hour for the large-volume group. CONCLUSIONS: The super-wet subcutaneous infiltration liposuction technique for both small- and large-volume reductions is safe and can be performed without adverse cardiopulmonary sequelae. Given the high urine outputs, the intraoperative fluid ratio can be further improved by possibly eliminating the replacement fluid altogether.

Reconstruction of acquired scalp defects: an algorithmic approach.

LEARNING OBJECTIVES: After studying this article, the participant should: 1. Understand scalp anatomy, hair physiology, and skin viscoelastic properties as they relate to scalp reconstruction. 2. Understand the principles that allow for aesthetic reconstruction of scalp defects. 3. Understand the use of local tissue rearrangement for reconstruction of specific areas of the scalp. 4. Understand the use of tissue expansion and free tissue transfer for scalp reconstruction. BACKGROUND: Reconstruction of scalp defects is required for acute trauma, tumor extirpation, radiation necrosis, and the repair of traumatic alopecia or cosmetically displeasing scars. METHODS: The proper choice of a reconstructive technique is affected by several factors-the size and location of the defect, the presence or absence of periosteum, the quality of surrounding scalp tissue, the presence or absence of hair, location of the hairline, and patient comorbidities. Successful reconstruction of these defects requires a detailed knowledge of scalp anatomy, hair physiology, skin biomechanics, and the variety of possible local tissue rearrangements. In nearly total defects, local tissues may be inadequate and tissue expansion or free tissue transfer may be the only alternatives. RESULTS: Plastic surgeons are now able to obtain coverage over the calvaria after the most devastating of defects; however, the challenge to the reconstructive surgeon today is to do so with excellent cosmetic results. Cosmetic scalp reconstruction requires restoration and preservation of normal hair patterns and hair lines. CONCLUSIONS: Successful reconstruction of the scalp requires careful preoperative planning and precise intraoperative execution. Detailed knowledge of scalp anatomy, skin biomechanics, hair physiology, and the variety of available local tissue rearrangements allows for excellent aesthetic reconstruction.