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The Adson cranial rongeur features straight shaft geometry with a 15 × 7mm cup-shaped jaw for controlled removal of bone during craniotomy and expanded spinal decompression. The wide jaw aperture captures larger bone fragments while maintaining precision contact with lamina and vertebral surfaces. At 210mm, the instrument provides balanced reach and control.
Features & Benefits
The Cushing decompression retractor is purpose‑built for holding open laminae, vertebral bodies, and spinal canals during laminectomy, laminoplasty, and intradural tumor removal. Its geometry supports hands‑free retraction of dura and nerve roots, freeing the surgeon's hands for delicate dissection and removal. Stainless steel construction ensures reliable performance across multiple surgical cases.
The Cushing pituitary rongeur is engineered for controlled bone removal during transsphenoidal pituitary surgery, with a 2 × 10mm bite capacity for trabecular material resection. The straight 152mm shaft supports precision control within the surgical field. Stainless steel durability withstands the repetitive gripping force across many neuro cases.
This extended Cushing pituitary rongeur spans 279mm for deeper sellar and suprasellar access during transsphenoidal tumor resection. The 2 × 10mm cup jaw bite provides secure tissue grip on pituitary and surrounding dural structures. Stainless steel construction delivers durable performance across demanding neuro procedures.
This Cushing pituitary rongeur delivers precise bone removal during transsphenoidal pituitary tumor resection. The up-angled shaft configuration provides improved visualization and access to the sella turcica during deep sellar work. The 2 × 10mm bite accommodates selective removal of intraspinal pituitary tissue without disrupting surrounding dural structures.
This D'Errico hypophysal forceps delivers cupped-jaw grasping for selective tumor tissue removal during transsphenoidal pituitary surgery. The 6mm cupped jaw accommodates soft tumor tissue without crushing, and the 220mm bayonet configuration provides offset visualization during deep sellar work. The 90mm working length supports controlled maneuvering within the sphenoid cavity.
The D'Errico-Adson cerebellum retractor combines the precision of Adson-pattern prongs with reinforced mass for deeper cerebellar and brainstem retraction. Its 4 × 4 sharp-prong array and angled geometry enable controlled manipulation of delicate hindbrain structures without slipping, while the 187mm length provides surgical reach into the posterior fossa. Slightly angled construction improves ergonomic approach.
The Dandy nerve hook with a 90-degree angled tip and straight shaft provides precise mobilization of spinal nerve roots and cranial nerves during skull base and spinal decompression approaches. The angled geometry permits sweeping underneath nerve roots without direct compression, while the 230mm length reaches deep within the spinal canal and posterior fossa. Reliable angle retention supports repeated procedural use.
This straight Dandy nerve hook supports atraumatic retraction and identification of cranial and spinal nerves during neurosurgery. The fine 228mm shaft allows delicate manipulation without neural injury, and the hook geometry prevents nerve slippage during prolonged retraction. Stainless steel construction withstands repeated reprocessing across routine neuro cases.
The Dandy nerve hook angles the blunt tip 90 degrees on a right‑angled 229mm shaft, sized for atraumatic lifting and retracting of nerves during neurosurgical and orthopedic exposure. The blunt tip preserves the perineurium, and the right‑angled shaft sets the hook clear of the operator's view.
Designed for precision cutting of small neural structures, these Dandy trigeminal scissors feature a curved blade with backward angled ring handles that maintain excellent visualization during delicate dissection. The 171mm length and ring grip provide stable tactile feedback during trigeminal nerve exposure and cranial nerve root division. The standard curve supports clean tissue planes without catch or bind.
Extended to 178mm, these Dandy trigeminal scissors provide enhanced reach during deep basilar and cerebellopontine angle work. The backward‑angled ring handles preserve the surgeon's line of sight to delicate neural anatomy while maintaining precise cutting control. The curved blade geometry follows neural contours naturally, supporting fine division of the trigeminal nerve and adjacent structures.
This double‑ended Davis brain spatula features 22mm and 25mm ends with an overall length of 203mm for controlled intracranial tissue manipulation.
This Davis-type brain spatula protects the cortex while a deeper structure such as the dura, ventricle, or vascular plane is approached. The 1-inch (25.4mm) blade width distributes retraction force evenly across the cortical surface to reduce parenchymal injury, and the 7-inch (178mm) length seats the spatula on the cranial frame while keeping the surgeon's hand clear. Stainless‑steel construction holds the malleable‑style profile through repeat sterilization.
Built at 38.1mm width, the Davis‑type brain spatula presents the widest standard malleable blade in the Davis family for major neurosurgical exposures. The wider blade displaces larger volumes of cortical tissue while remaining gentle on the underlying surface.
The Davis‑type brain spatula at 31.8mm width carries a malleable blade on a 178mm body, sized for moderate‑to‑wide brain tissue retraction during neurosurgical exposure. The blade bends to the chosen angle at the field, holding cortical surfaces back without crushing.
Sized at 12.7mm, the Davis‑type brain spatula is the narrowest standard malleable blade in the Davis family, suited to the most focal neurosurgical retraction where minimal cortical displacement is wanted. The 178mm length keeps the handle clear of the craniotomy.
The Davis brain spatula (6.3mm width, 178mm length) gently separates dura and brain parenchyma during cerebral exposure and tumor dissection. Its slender, straight blade follows natural tissue planes without causing bruising or excessive retraction. The handle design provides controlled, tactile feedback during microscopic neurosurgical work near eloquent cortex.
The 19mm Davis‑type brain spatula carries a narrower malleable blade than the wider variants, sized for focal neurosurgical retraction where a smaller working face is wanted. The 178mm length keeps the handle clear of the craniotomy, and the blade bends to the chosen retraction angle.
The Davis brain spatula (9.5mm width) provides broader tissue contact for controlled dural elevation and ventricular exposure during intracranial procedures. At 178mm, the straight profile maintains excellent visibility along the surgical axis while protecting underlying structures. The wider footprint distributes retraction force across the meningeal and cortical surfaces.
The Davis brain spatula delivers a broad 16mm blade geometry optimized for white matter dissection and cortical surface retraction during microsurgical approaches to the cerebral hemispheres. Its straight shaft provides direct visualization along the sulcal planes, while the 178mm length enables deep access without restricting surgical field sight lines. The flat blade profile minimizes trauma to adjacent gyri during manipulation.
This slightly curved neurosurgical dissector features a blunt 6mm tip designed for safe tissue plane separation. The round knurled handle provides secure grip during delicate dissection, and the 267mm length accommodates access to deep midline and paramedian structures. Blunt geometry minimizes inadvertent neural tissue trauma during dissection in confined spaces.
The Hardy pituitary spoon is a curved microsurgical instrument designed for controlled removal of pituitary adenomas and tissue during transsphenoidal hypophysectomy. The 4mm curved bowl geometry and bayonet shape allow precise tissue cup and removal from within the sella turcica. The 125mm working length provides adequate reach while maintaining tactile control in confined sellar spaces.
The Krayenbuehl nerve hook's ball tip minimizes risk of traction injury when mobilizing delicate cranial nerves and nerve roots during skull base and spinal surgery. At 184mm with a straight geometry, it provides excellent reach and control during brainstem manipulation and dural opening. The rounded tip distributes load across a wider surface, protecting the epineurium and axonal architecture.
This extended Love‑Gruenwald pituitary rongeur provides lengthened reach for deeper spinal or skull base exposures. The 280mm working length accommodates access to midline bony lesions in deeper anatomic planes. The straight shaft maintains alignment and control during precision bone removal in complex neuro-oncologic cases.
This Love‑Gruenwald pituitary rongeur supports transsphenoidal access with a straight shaft and 3 × 10mm bite geometry. The compact 127mm working length allows precise maneuvering within the narrow sphenoid corridor. Stainless steel construction delivers lasting performance across repeated pituitary and skull base cases.
This McCulloch nerve root retractor features a 6mm blade and a 127mm shaft length for controlled retraction of neural structures.
The McCulloch ball‑tipped probe carries a 4mm tip on an angled 241mm body, sized for atraumatic neural and dural exploration during neurosurgical and spine work. The ball tip preserves the underlying structure while the angled shaft sets the working face away from the operator's view.
Stepping up the working tip to 7mm, this McCulloch ball‑tipped probe on a 241mm angled body suits exploration where a slightly larger tactile face is wanted than the 4mm version. The ball tip preserves underlying tissue while delivering more tactile feedback.
Multiple toothed muscle blades distinguish the McCulloch retractor for controlled spinal cord and nerve root retraction during laminectomy and dural sinus approaches. The interlocking tooth pattern distributes lateral retraction force evenly across delicate neural tissue while minimizing stretch injury. At 50mm length, the blade geometry enables proximal fixation in the surgical canal without obscuring the operative field.