Due to the three-dimensional configuration of the auricle and cartilage, surgeons encounter significant challenges in the reconstruction of auricular defects in anterior regions such as the antihelix and triangular fossa. Local flaps, skin grafting, and wedge excision are currently used in these locations. Postauricular flaps are the most common of these techniques, due to their advantages that include low morbidity, a well-hidden scar, direct closure, and good color match to the ear skin [1]. However, the lack of underlying vasculature and perichondrium may lead to graft necrosis. Moreover, wedge excision cannot be performed in patients with defects of the antihelix or triangular fossa because such patients are vulnerable to severe ear deformities. We modified a flip-flop flap to reconstruct anterior defects of the ear across the antihelix and triangular fossa. Our technique is a one-stage, random-pattern island flap surgery, and allows a shorter operation time and reduced losses at the donor site, while still leading to satisfactory treatment outcomes. Here, we describe our technique and its outcome. This study was reviewed and approved by the ethics review board of the Inje University Health Center. A 70-year-old man visited us with a chief complaint of Bowen's disease in the right ear. The patient underwent excision of the tumor with adequate circumferential and deep margins, including the perichondrium. The defect, located throughout the antihelix and triangular fossa, was oval in shape and 2.0×1.8 cm in size, with exposed cartilage (Fig. 1). Fig. 1 The defect, located throughout the antihelix and triangular fossa, was oval in shape and 2.0×1.8 cm in size, with exposed cartilage. We decided to create a 30% overlap in the medial direction. Under local anesthesia, we performed preoperative marking for the skin island, based on the size of the anterior auricular defect, for which we intended a 30% overlap in the medial direction (Fig. 1). A cartilage window was then drawn at the center of the overlap between the marked area and the actual defect. Thus, we attempted to provide an entrance for skin flap placement (Fig. 2). Fig. 2 After creating a skin island, we removed a small, slender piece of cartilage to provide an entrance for the skin flap. After being drawn on the anterior auricular surface, the pattern was marked on the back and then redrawn. It was then redesigned by extending the top side by approximately 10 mm, in line with the sulcus axis, thus leaving the lower base intact. In other words, it was shaped into an elongated orb alongside the axis of the sulcus. We thus made it easier to reduce the tension in the central pedicle during rotation and to suture the donor site. We placed one third of the skin island over the mastoid area and the remaining two thirds of the skin island over the postauricular surface. After excising the designated area, we elevated the skin flap while preserving the central subcutaneous pedicle. Once the flap was observed to be sufficiently elevated, we rotated it at an angle of 120° around the long axis through the cartilage window (Fig. 3). The flap was closed using interrupted prolene 6-0 sutures, and the postauricular donor site was closed using continuous vicryl 5-0 and prolene 5-0 sutures. Fig. 3 Schematic diagram. (A) Schematic illustration of a conventional flip-flop flap. There is an exact match in surgical design between the anterior defect site and the posterior donor site. The lateral side (**) of the donor site exits anteriorly through ... The donor site was easily closed through direct repair, without other procedures. No differences were observed in the color and thickness of the skin between the flap and the anterior auricle. Moreover, the patient did not develop postoperative infections or flap loss. Furthermore, at a follow-up, the patient had no ear asymmetry or other complications, such as notable scarring (Fig. 4). Fig. 4 Five-month postoperative follow-up views. (A, B) Anterior and posterior aspects of the ear. In 1972, Masson [2] first reconstructed anterior auricular defects using subcutaneous pedicle postauricular flaps. These flaps have also been referred to as revolving or flip-flop flaps, or as posterior auricular rotation flaps, and they have been reported to be appropriate for reconstructing defects on the scapha, triangular fossa, antihelix, and conchal bowl. The advantages of this technique include the availability of well-vascularized skin for the coverage of large auricular defects and a one-stage operative procedure [3]. Since first being introduced, Masson's flap has been used by many surgeons. Due to the short length and immobilization of the subcutaneous pedicle, however, it has limitations in lowering the ear projection and the depth of the sulcus. In order to increase flap mobility, some authors have described postauricular axial pattern flaps, in which the posterior auricular artery or the superior auricular artery is used as a pedicle [4]. However, these flaps are disadvantageous in that they require careful dissection and may result in morbidity. Therefore, because they are not used frequently, other researchers have developed a de-epithelialized postauricular flap; its advantages include higher safety and mobility compared to the subcutaneous pedicle flap and lower morbidity than the axial flap. Nonetheless, it is problematic that additional procedures are required for de-epithelialization, and ear deformities may occur as a result of the increased area of the postauricular donor site. Our technique can be summarized as follows. First, we approached the postauricular donor site proximally to the sulcus in the medial direction rather than in same region as the defect. Thus, we were able to obtain a sufficient amount of postauricular skin, even in patients with defects of the outer edge of the ear, such as the antihelix or scapha. Second, we rotated the postauricular skin island at an angle of 120°, unlike conventional methods in which it is rotated at an angle of 180° through the cartilage [5]. This is useful when there is no parallel relationship between the axis of the largest defects and that of the sulcus or when the angle is approximately 90°. Aligning the maximum width of the defect to the postauricular sulcus axis, which has sufficient space, reduced the size of the defect in the donor region while simultaneously allowing a safe blood supply. Third, we did not create the cartilage window at the center of the flap island, but instead made it as small as possible in the overlapping region between the defect and the donor site. Thus, we increased the stability of the skin flap by preventing the pedicle from being entangled. We modified a postauricular island flap to reconstruct defects across the antihelix and triangular fossa. Our technique was useful not only in maintaining the contour and three-dimensional structure of the auricle, but also in shortening the operation time and recovery period.