Electrical impedance sensing dental drill system configured to detect cancellous-cortical bone and bone-soft tissue boundaries

Abstract

A dental drill system with electrical-impedance sensing indicates when a bit of the drill system approaches cortical-cancellous bone, or bone-soft tissue interfaces. The drill system has a dental drill handset having a cannula bearing electrically coupled to a drilling bit, the drilling bit having an electrically insulated portion and an exposed portion. The cannula bearing is coupled to an electrical impedance spectroscopy sensing device configured to measure impedance between the cannula bearing of the dental drill handset and a ground plate, and a processing system uses EIS measurements to distinguish when the bit of the drill system approaches cortical- or cancellous bone, or bone-soft tissue interfaces.

Claims

1. A dental drill system with electrical-impedance sensing (EIS) configured to indicate whether a bit of the drill system is approaching a cancellous-cortical bone interface or a bone-soft tissue interface comprising: a dental drill having in its handset a cannulated bit, the cannulated bit having an insulating coating extending from near a cutting end of the bit to a handset end of the bit, a cannula bearing electrically coupled to an uninsulated interior of a cannula of the cannulated bit, an EIS measurement and calculation unit configured to measure impedance between the cannula bearing and a ground plate, and a processing system configured to distinguish when the bit of the drill system approaches a cancellous-cortical bone or bone-soft tissue interface.

2. The dental drill system of claim 1 wherein the insulating coating of the drilling bit is insulated with a diamond-like-carbon (DLC) coating.

3. The dental drill system of claim 2, wherein the EIS measurement and calculation unit is configured to measure impedance at least two frequencies in the range of 100 to 100000 Hertz.

4. The dental drill system of claim 1 the wherein EIS measurement and calculation unit provides a voltage-limited current at each of a plurality of frequencies and measures a resulting voltage and phase.

5. The dental drill system of claim 4, wherein the EIS measurement and calculation unit is configured to measure impedance at least two frequencies in the range of 100 to 100000 Hertz.

6. The dental drill system of claim 1 wherein the EIS measurement and calculation unit is configured to provide a visual and/or aural alarm when the drill bit approaches cortical bone.

7. The dental drill system of claim 6, wherein the EIS measurement and calculation unit is configured to measure impedance at least two frequencies in the range of 100 to 100000 Hertz.

8. The dental drill system of claim 1 wherein the EIS measurement and calculation unit is configured to measure impedance at least two frequencies in the range of 100 to 100000 Hertz.

9. A method of detecting approach of a bit to cortical bone, or approach of a bit to bone-soft tissue interface, while drilling bone with the bit comprising: providing an insulating coating extending from near a cutting end of the bit to a handset end of the bit; contacting the bit with a cannular bearing; driving a voltage-limited current between the bit and a ground plate at least one alternating current frequency; measuring voltage and phase between the bit and ground plate; determining impedance from the measured voltage and phase; and generating an alarm when the impedance changes indicating approach to cancellous-cortical bone interfaces or bone-soft tissue interfaces.

10. The method of claim 9 wherein the voltage-limited current is driven at multiple frequencies between 100 and 1,000,000 Hertz.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a block diagram of the drilling system with electrical impedance spectroscopic sensing.

(2) FIG. 2 is a sketch of a drill bit of the current drilling system.

(3) FIG. 3 is a photograph showing an embodiment of a drill having a bit with cannular bearing attached.

(4) FIG. 4 is an illustration of electrical resistance and reactance of cancellous and cortical bone samples measured with a prototype integrated on a Nobel Biocare Drill with a 2 mm twist bit.

(5) FIG. 5 is a photograph of a DLC-coated drill bit having a bare cutting end.

(6) FIG. 6 illustrates contrast of normalized mean resistance and reactance of cancellous and cortical bone measured with a prototype integrated on a standard Nobel Biocare Drill with a drill bit in ex vivo bone.

(7) FIG. 7 illustrates contrast of normalized mean resistance and reactance of cancellous and cortical bone measured with a prototype integrated on a standard Nobel Biocare Drill with a drill bit in fresh, in situ, bone.

(8) FIG. 8 is a flowchart of a method of detecting approach of a drill bit to cortical bone during surgical procedures.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(9) The vastly different cellular constituents of cortical and cancellous bone provide a spectrum of electrical charge carrying and charge storage capabilities, which are represented by electrical conductivity (σ) and permittivity (ε), respectively (σ and ε are inversely related to resistance and reactance). When recording these electrical properties over a broad range of frequencies (100's of Hz to 10's of MHz), as is done in Electrical Impedance Spectroscopy (EIS), cortical and cancellous bone have been reported to differ significantly. Studies have investigated electrical impedance measurements in pedicle screw insertion into vertebrae and have shown that electrical property differences between cancellous and cortical bone can be used to guide surgeons through vertebral bone.

(10) We describe herein an EIS device integrated with a drill configured for drilling holes in bone, such as may be required for a variety of surgical procedures in dentistry and some non-dental surgeries. The drill is particularly configured for measuring bioimpedance spectra in vivo during the initial osteotomy of dental implant procedures. The drill is particularly adapted for measuring the electrical impedance spectra of bony structures in vivo as the drill is advanced into the structure. This EIS drill provides real-time feedback to the clinician, as either an auditory or visual signal, allowing the clinician to stop drilling before perforation of the cortical layer occurs (enabling immediate clinical intervention if necessary). In a particular embodiment, the drill is a dental drill.

(11) The EIS-sensing drill system 100 is illustrated in FIG. 1. A dental drill handset 102 contains a high-speed motor and driveshaft 104 leading to a right-angle bevel gear unit 106, the bevel gear unit and a housing 110 of the driveshaft 104 being insulated with an insulating coating 108. Coupled to the bevel gear unit is a drilling bit 112 having an insulated portion 114 and a bare, cutting, portion 116. Bare cutting portion 116 is a portion of a ball-like burr in some embodiments and a tip of a twist-drill bit in other embodiments; the insulated portion extends from the cutting portion to a handset end of the bit that is mechanically coupled to into a dental drill handset. Within bevel gear unit 106 is a cannular bearing 118 electrically coupled to bit 112. Handset 102 has an umbilical tubular housing 120 holding a tube 122 for irrigation fluid, an electrical drive wire for the motor of handset 102, and an electrical wire adapted for coupling the cannular bearing 118 to an electrical impedance spectroscopy (EIS) measurement and calculation unit 130, EIS measurement and calculation unit 130 also couples through another wire 132 to a second electrode plate 134. Within EIS measurement and calculation unit 130 are an EIS stimulus unit 136 capable of operation at 100, 1000, 10000, and 100000 Hz under direction of processor 138 and an EIS impedance measurement unit 140. In alternative embodiments, EIS impedance measurement and calculation unit 130 is capable of operation at two or more frequencies in the 100 Hz to 1 MHz range. Processor 138 has a memory 142 with EIS measurement firmware and classifier firmware 144, the classifier firmware adapted to use EIS measurements to determine whether bit 112 is drilling in cancellous or cortical bone and to announce which bone type bit 112 is in using indicator 146.

(12) A twist-drill embodiment is illustrated in more detail in FIG. 2. A twist-drill bit 160 has a bare or uninsulated end 162 with cutting edges that may contact and drill holes in bone. Bit 160 also has an electrically insulated portion 164 bearing a coating of diamond-like carbon (DLC), a coating that is both very hard such that it wears little while holes are being drilled in bone, and electrically of high resistivity, the coating of DLC extends throughout the remainder of the exterior of bit 160 to the drill end of bit 160, including portions that engage bevel gear of drill head 170, and including portions over flutes 171. Bit 160 also has an uninsulated axial hole 172 extending from drill end of bit into, but not all the way through, the bit.

(13) Within the axial hole 172 and in electrical contact with the uninsulated surface of bit 160 in that hole is an uninsulated end portion 174 of cannular bearing 166. Cannular bearing 166 extends from bit's 160 end through insulation 176 to electronics EIS measurement and calculation unit 130 (FIG. 1). Drive shaft 178 and bevel gear 180 rotate to drive bevel gear 168 of drill head 170 to rotate bit 160 to drill the holes into bone.

(14) FIGS. 1 and 2 are schematics, FIG. 3 is a photograph showing an embodiment of an experimental drill 202 having a bit 204 with cannular bearing 206 and insulated lead 208 attached, and FIG. 4 is a photograph showing a pair of uninstalled cannular bearings 210. In an embodiment, cannular bearings 210, 206, are formed of stainless steel.

(15) In various embodiments the uninsulated end portion 174 of bit 160, or uninsulated ball portion of bit 116, is from one to three millimeters in length.

(16) Operation of the EIS Drill System:

(17) The EIS measurement and calculation unit, drill, and bit with cannular bearing together form the EIS drilling system. Positioning the bearing 206 within the drill bit's cannula does not decrease the surgical working space and still allows for irrigation through the intra-cannular channel or around the exterior surface of the drill bit. The cannular bearing connects to a lead that interfaces with the impedance analyzer. Similarly, the return electrode 134 (FIG. 1) connects to another lead that interfaces with the impedance analyzer. A voltage-limited, alternating current (AC) current is applied between the two electrode elements at several frequencies and the voltage and phase induced between them is recorded. From these measurements, impedance is calculated as the ratio of voltage to current.

(18) Impedance (Z) is calculated as the ratio of the measured voltage to the injected current; we regard the impedance as a complex quantity, consisting of a real resistive component (R) and an imaginary reactive component (X), according to the equation, Z=R+jX. The electronics box computes an R and X measurement at each frequency being tested. From those we compute impedance, conductivity, resistivity, and the like.

(19) We have shown in previous experiments in ex vivo and in situ pig femurs that cortical bone has a higher resistivity and impedance than cancellous bone. The ratio of cortical-to-cancellous resistivity ranged from 1.28-1.48 in ex vivo bone and from 2.82-2.94 in fresh in situ bone. As a result, we expect that, as the drill bit moves through cancellous bone towards a cortical interface we will see an increase in impedance/resistivity as we approach that interface.

(20) In an embodiment, the EIS measurement and calculation unit is configured to provide a visual and/or aural alarm when the drill bit approaches cortical bone.

(21) Clinical use of this device involves using the drill to create the initial osteotomy (hole in the bone) marked for implant insertion. Electrical properties, specifically the resistance and reactance of the bone, are recorded over a single or multiple frequencies as the drill is advanced into the bone. These measurements will be input into a real-time classification unit used to sense an approaching tissue transition (i.e. the cancellous-cortical interface). A visual or auditory signal that increases in repetition rate, based on the changing impedance, will be used as clinician feedback.

(22) We have collected a significant dataset of ex vivo and in situ electrical properties of cortical and cancellous bone and have shown significant impedance contrast between the two bone types.

(23) In the ex vivo experiment, we positioned standard cannulated drill bits three millimeters deep into 10 samples each of cortical and cancellous bone freshly harvested from swine and recorded impedance from 100 Hz-1 MHz at 41 frequencies. We demonstrated that there are significant R and X differences (p<0.05) between the two bone types with contrasts in resistance of 41%, 37%, 29%, and 32% at 0.1 kHz, 1 kHz, 10 kHz, and 100 kHz, respectively. These trends, recorded with our prototype, are similar to those reported previously for cancellous and cortical bone.

(24) In the in situ experiment, we used a custom DLC-coated drill bit to record impedances from 40 samples each of cortical and cancellous bone in the femurs of pigs 30 minutes after euthanasia. We demonstrated that there are significant R and X differences (p<0.001) between the tissue types, with a maximum resistance contrast of ˜300% at 100 kHz and a maximum reactance contrast of ˜250% at 1 kHz.

(25) The electrical impedance sensing is responsive not just to the tissue type the tip is in, but to tissue types near the tip. The system can therefore watch for impedance changes as the drill penetrates bone and generate an alarm when the impedance changes indicate the tip is approaching a cancellous-cortical bone interface, or when the tip is approaching a bone-soft tissue interface; bone-soft tissue interfaces include interfaces between bone and blood vessels, nerves, sinus lining, muscles, and other non-ossified tissues.

(26) Features

(27) Features of this dental drill system with electrical-impedance-spectroscopy sensing include:

(28) 1) a coated dental drill bit as the sensing or driving electrode,

(29) 2) a Diamond-Like-Carbon (DLC) coating to insulate all but the distal few millimeters of the drill bit,

(30) 3) an intra-cannular bearing to interface the drill bit with the impedance-sensing module,

(31) 4) collecting impedance measurements at multiple frequencies for this particular surgical drill application, and

(32) 5) extending the interface detection feature beyond pure threshold detection.

(33) In addition, by interfacing our system to the dental implant drill through the cannular space, we do not need to augment the drill in any way nor do we decrease the working volume available to the surgeon. Irrigation is still possible despite the presence of the bearing, allowing for surgeons to continue using cannulated drill bits as they were intended.

(34) DLC coatings are designed to have extremely high hardness (4000-9000 HV), high resistivity (up to 10.sup.6 Ω-cm), and are bio-compatible. By applying this insulating coating to the majority of the drill bit and leaving only the distal 1-3 mm exposed for sensing, we provide more robust and repeatable impedance measurements that are not dependent on drill bit depth into the material. While some prior art includes provisions for an insulating material applied to the drilling device, they do not specify the type of insulating material, nor do they leave an area on the distal end exposed for sensing.

(35) Collecting impedance measurements at multiple frequencies, instead of a single frequency, has the potential for better classification between cancellous and cortical bone. The increased number of measurements will allow us to explore additional features that can be used to contrast the two bone types. Most prior art is based on threshold detection at a single frequency to alert clinicians of an approaching tissue interface. We use multiple features and algorithms to find an optimal combination to use for interface detection.

(36) In an embodiment, the method of detecting approach of a bit to cortical bone while drilling bone with the bit includes providing 302 (FIG. 8) an insulating coating extending from near a cutting end of the bit to a handset end of the bit, and contacting 304 the bit with a cannular bearing. Then the EIS measurement and calculation unit drives 306 a voltage-limited current between the bit and a ground plate at least one alternating current frequency and measures voltage and phase, then determines 308 impedance from measurements of voltage and phase between bit and ground plate; and generates 310 an alarm when the impedance changes indicating approach to cancellous-cortical bone or bone-soft tissue interfaces.

(37) In an alternative embodiment, a contact portion of the handset end of the bit is bare of the DLC insulating coating, and the handset is modified to provide electrical contact from the EIS measurement and calculation device to that bare portion of the handset end of the bit while isolating the remainder of the drill handset from the EIS measurement and calculation device.

(38) Combinations of Features

(39) A dental drill system designated A with electrical-impedance sensing (EIS) configured to indicate whether a bit of the drill system is approaching a cancellous-cortical bone interface or a bone-soft tissue interface includes a dental drill having in its handset a cannulated bit, the cannulated bit having an insulating coating extending from near a cutting end of the bit to a handset end of the bit a cannula bearing electrically coupled to an uninsulated interior of a cannula of the cannulated bit, an EIS measurement and calculation unit configured to measure impedance between the cannula bearing and a ground plate, and a processing system configured to distinguish when the bit of the drill system approaching a cancellous-cortical bone or bone-soft tissue interface.

(40) A dental drill system designated AA including the dental drill system designated A wherein the electrically insulated portion of the drilling bit is insulated with a diamond-like carbon (DLC) coating.

(41) A dental drill system designated AB including the dental drill system designated A or AA wherein EIS measurement and calculation unit provides a voltage-limited current at each of a plurality of frequencies and measures a resulting voltage and phase.

(42) A dental drill system designated AC including the dental drill system designated A, AA, or AB wherein the EIS measurement and calculation unit is configured to provide a visual and/or aural alarm when the drill bit approaches cortical bone.

(43) A dental drill system designated AD including the dental drill system designated A, AA, AB, or AC wherein the EIS measurement and calculation unit is configured to measure impedance at least two frequencies in the range 100 to 100000 Hertz.

(44) A method designated B of detecting approach of a bit to cortical bone, or approach of a bit to bone-soft tissue interface, while drilling bone with the bit includes providing an insulating coating extending from near a cutting end of the bit to a handset end of the bit, contacting the bit with a cannular bearing; driving a voltage-limited current between the bit and a ground plate at least one alternating current frequency; measuring voltage and phase between bit and ground plate; and determining impedance from measured voltage and phase; and generating an alarm when the impedance changes indicating approach to cancellous-cortical bone interfaces or bone-soft tissue interfaces.

(45) A method designated BA including the method designated B wherein the voltage-limited current is driven at multiple frequencies between 100 and 100000 Hertz.

CONCLUSION

(46) Changes may be made in the above methods and systems without departing from the scope hereof. It should thus be noted that the matter contained in the above description or shown in the accompanying drawings should be interpreted as illustrative and not in a limiting sense. The following claims are intended to cover all generic and specific features described herein, as well as all statements of the scope of the present method and system, which, as a matter of language, might be said to fall therebetween.