Clinical Corner: Information on Dental Procedures
Articles
What's Hot: Dr. Glazer on Jazz
Combating Hidden Decay with Early Detection
Atraumatic Removal of Defective Crowns
Balancing: The Art, Science and Business of Dentistry
Intra-Oral Preparation of Titanium Abutments in Order to Obtain Ideal Angulations and Contours
SS White Express Line High Speed Laboratory Metal Finishing Burs
Direct Preparation Of Preexisting Implant Abutments For Case Rehabilitation
Flextime Xtreme: The 80/20 Rule
Fast and Smooth - Efficient Crown Preparation With Carbide Instruments
When Advancing the Bur, One Can Feel the Presence of Dentinal Caries
Precision Trimming and Finishing of Current Dental Restorations Using the Safe End Bur System
Indirect Restorative Tooth Preparation: Extreme Efficiency and Accuracy
Creating Maximum Efficiency and Accuracy In Indirect Restorative Tooth Preparation
Preparation Protocol To Ensure Predictable Aesthetic Restorations
Tooth Preparation Mastering Quality and Efficiency
Fissurotomy: Proactive Treatment for Incipient Decay
Anatomically Adapted Carbide Finishing Burs - Creating Super-Smooth Composite Surfaces in Two Steps
Directions for Use: Dr. David Clark Kit
Placing Traditional Sealants with Enhanced Magnification:
Methodology to Increase Both Short-term and Long-term Success - David Clark, DDS
How to Quickly and Conservatively Restore a Natural Shine after Orthodontic Bracket Removal
SS White Surgical Length Oral Surgery Burs:
Atraumatic Removal of Teeth for Maximum Bone Preservation
"Placing Traditional Sealants with Enhanced Magnification:
Methodology to Increase Both Short-term and Long-term Success"
David Clark, D.D.S.
Traditional dental sealants, which have ostensibly become restorative dentistry’s most promoted preventive procedure also have one of dentistry’s highest failure rates. A well-publicized CRA study¹ confirmed an unacceptably high failure rate for sealants during a 10-year follow-up. Not surprisingly, microscope clinicians often change their protocol or discontinue placing sealants once they purchase their first microscope.
At the inaugural meeting of the Academy of Microscope Enhanced Dentistry, there was unanimous consensus: traditional sealants rendered with no or low magnification are inappropriate in a microscope-centered practice. Many other aspects of sealants were also challenged. The questions are, “How much magnification is enough,” and “What is the microscope and research teaching us about the practical application of sealants?”
Fundamentals of Clinical Magnification
The operating microscope offers more than just simply higher magnification than oculars (loupes), it offers better resolute magnification. Oculars have been very helpful and may always have a role in dentistry, but the optics are crude when compared to the infinity corrected optics of a stereoscopic microscope (Figures 1-4). When combined with the shadow-less coaxial light source, operating microscopes transform the clinician’s potential for accuracy in nearly every aspect of the different disciplines in dentistry.
Figure 1
Oculars (loupes) rely on convergent vision that essentially requires a crossing over of images. This form of magnification creates increasing problems and eyestrain as magnification increases.
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Figure 2
Convergent 8x magnification and a representation of the 2 images that your brain receives as you begin to focus. |
Figure 3
Incomplete merging of images, which is a common occurrence. Both images also demonstrate the visual noise in the background of loupes. |
Figure 4
Infiniti corrected (parallel) optics at 24x. There is no eyestrain. Loupes magnification at 8x and above becomes excruciating for most humans. |
Think of magnification in terms of television screens: a 21-inch screen has twice the surface area of a 15-inch screen. Dr. Assad Mora, one of the pioneers of full-time microscope utilization in prosthodontics, explains that increasing levels of magnification produce a squared, not linear relationship to visual acuity. In other words, 10x magnification allows the human retina to acquire 100 times more information; 20x allows 400 times the visual information.
Years ago I used 2.5 power loupes for all my restorative procedures. Nine years ago we began to integrate the microscope and now use it full time in our practice. As I use the microscope at 16 power to examine the amalgams I placed years ago at 2.5 power, I am proud of their appearance. The sealants that I so carefully placed at 2.5 power, however, are often an embarrassment. We find that composite and porcelain require significantly higher levels of magnification due to the difficult handling properties, lack of visual contrast with tooth structure, and the rigors of bonding. I find that 10x is the bare minimum for these new techniques, and routinely find myself working at even higher magnification levels.
The Quiet Revolution in Dentistry
The operating microscope is transforming restorative dentistry today the same way that it transformed endodontics 10 years ago. A case in point: just as the microscope revealed the complexity of root canal morphology, the anatomy of occlusal defects is revealed to be more complex than originally thought (Figure 5). I teach that we should refer to partially or no coalesced enamel as “cul-de-sacs and doglegs” as opposed to “pits and fissures.” This point is crucial. The most insidious defects are the cul-de-sacs that masquerade as coalesced enamel at less than 16x magnification. In addition, many defects extend laterally (much like calcified root canal systems in molars), hence the term dogleg.
The 9 Fatal Flaws of Traditional Sealants
(1) Traditional Diagnosis
Explorers and radiographs are the traditional tools used to detect occlusal decay. Microscopic examination of a desiccated tooth yields a wealth of information regarding incipient pathology. The translucent nature of enamel gives subtle clues regarding early microleakage, early in-complete fractures and the true nature of enamel defects and occult decay. Other high-tech modalities can be helpful but are no substitute for a trained eye at 24x or 40x.
(2) Sealing Over Stained Grooves
All but the most superficial portions of these grooves are inaccessible to a toothbrush bristle. This allows very stubborn deposits that act more like calculus than plaque. Even with prolonged application of a prophy jet, this area often remains too contaminated to create a successful bond. It generally requires abrasion with a bur, air abrasion, laser, or similar cutting modality (Figure 6).
Figure 5
A sectioned molar is viewed at 16x. Note the cul-de-sac that is also divergent from the direction of the occlusal portion of the groove (a classic dogleg). Parallel-sided preparation of the groove, especially without the microscope, would not allow visualization of the true extent of the defect.
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Figure 6
Microscopic comparison of Fissurotomy Burs manufactured by S.S. White. Micro NTF (top) and Original Fissurotomy (below) compared with typical laser tips. The Fissurotomy Burs are narrower at the tip. The width, depth, and continuity of the cuts into dentin are the most crucial in dental crack and fracture avoidance. |
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(3) Using Paste Composite Alone to Restore Micropreps
Manufacturers, in their zeal to create wear-resistant composites (Figures 7 and 8), are now selling pastes that are often too stiff to adapt well to grooves or anything small. The unidose syringes deliver inconsistent viscosities that further exacerbated the problem.
Figure 7
Stiff paste composite at 24x. Inconsistent viscosities wreak havoc on adaptation.
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Figure 8
Note how the distal of the composite appears slightly lifted and no adaptation to grooves was possible. |
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(4) Traditional Sealants on Second Molars
These teeth are typically very poorly erupted on the distal aspect (Figures 9 and 10). In 10 years of microscopic examinations, I have observed that nearly all-traditional sealants on the distal half have either fallen off, are leaking, and/or create overhangs where they flowed over the gingiva.
Figure 9
Typical eruption of a second molar in an adolescent.
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Figure 10
Disclosing solution demonstrates the original level of the gingival crest before tissue retraction provided by clamp. Arrows follow the rise of the gingiva as it approached the distal. The incessant action of the sulcular pump virtually guarantees distal fluid contamination when no retraction is performed. |
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(5) Sealing Over Decay
First of all, most traditional sealants on molars leak, so the concept is an oxymoron. More importantly, even if it were possible to hermetically seal a tooth, the research has shown that bacteria can survive in seemingly impossible environments. Leaving decay behind is simply wrong.
(6) Relying on Phosphoric Acid to Clean and Deplaque the Tooth
I am always surprised that good clinicians assume that acid-etch removes plaque. The microscope confirms that it does not. In fact, research has shown that acid-etch does not even kill many strains of bacteria, much less remove them.
(7) Sealant Maintenance
This is a protocol that has emerged from the shortcomings of both the traditional sealant technique and the material itself. Why do we accept such a compromise with sealants? Many parents are asking this same question. In my practice I do a very different technique under the microscope which can last decades or even a lifetime, but sealants are still the standard of care. In reality, traditional sealants rarely wear out.
We see that they crumble around the margins, leak, chip away, and fall out (Figure 11). Repeatedly sealing over these teeth is a bit like painting over rust.
Figure 11
Maxillary second molar at one year after sealant placement. The distal portion of sealant has fallen off. A 24x view of the groove shows typical contamination that was probably not well addressed at time of sealant. A view of the intact portion of sealant demonstrates marginal breakdown of bond; sealant retention does not necessarily indicate success.
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(8) Placing Traditional Sealants in Teeth That Have Been Extensively Prepared
Traditional sealant material is either not filled or lightly filled (Figure 12). Clinpro Sealant (3M ESPE), for example, has filler content of 6% by weight. By contrast, Filtek Flow flowable composite (3M ESPE) has filler content of 68%. Sealant material was never designed to withstand occlusal forces.
(9) Sealants Placed With Low or No Magnification
One of the advantages to high magnification (10x and above) is the elimination of bubbles and voids. The viscous nature of sealants, flowable composites and paste composites makes the incorporation of bubbles and voids virtually impossible to avoid. High magnification allows the clinician the ability to avoid or detect and remove these defects prior to curing. Figure 13 shows the effects of a bubble that was unseen by the clinician at the time of sealant placement.
Figure 12
High magnification of sealant that was placed in a molar after moderate tooth preparation. Note the crack in the sealant. Sealant material lacks the strength required for this application.
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Figure 13
Depending on size and location, bubbles cause aesthetic failure or overall failure. The microscope reveals that they are a very common problem. |
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IN A NUTSHELL…
Sealants often do not flow anywhere near the depth of enamel defects. The grooves are often so badly contaminated that the bond is poor. The only decent bond is often outside the grooves on cusp inclines where the sealant wears off in a few months. When you cut open the grooves, the sealant material is no longer appropriate because it is not a restorative material. Aggressive tissue retraction may be the only way to isolate many molars properly. High magnification is ideal (Figures 14-16).
Figure 14
NarrowerNTF Fissurotomy Bur at two-thirds depth. Notice the rounded tip and the slightly tapered sides to the Fissurotomy Bur. This is important as the bur is designed to eliminate all internal sharp line angles. Internal line angles combined with the forces of mastication can lead to premature fracturing.
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Figure 15
Canula of 3M Filtek, which is smaller than some other brands, does not come close to depth of microprep. The microscope reveals the futility of injecting directly. Recommended protocol is to place on the triangular ridge of the functional cusp and then tease into the groove at 12x or 16x. |
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Figure 16
The physical and optical characteristics of flowable composite make bubble formation and recognition more problematic than the sealant material. Here at 8x (left) we see a tooth restored with flowable composite that has no apparent bubbles. When we cut into the composite, we find multiple bubbles and voids (12x view, right)
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Should We Tinker with Improving Sealants or Rethink the Entire Approach?
Traditional sealants have been shown to be effective in reducing decay and will likely remain common in HMO settings, public assistance dentistry and third world countries. Ultimately, however, traditional sealants are temporary in nature. With the advent of high-level magnification, an entirely new approach is indicated.
Microscope-Enhanced, Lifetime Dentistry: The MDMIPC
We inform our patients that we are committed to creating dentistry that has the potential to last a very long time. That requires the microscope, an unhurried schedule and a fair fee that may not resemble the insurance UCR schedule du jour.
The microscope-delivered minimally invasive posterior composite (MDMIPC) will now be presented. Other excellent parallel procedures are being performed at high magnification. The rationale behind this particular approach will be explained.
Step 1—rubber dam. Goals are to retract gingiva, aid in microscopic visualization, eliminate contamination and create the ethereal experience of a controlled field, dark background and effortless microscope use. Neurosurgeons describe the experience as “deep sea diving narcosis.” Utilizing a microscope on an uncontrolled field is possible but not enjoyable.
Step 2—apply disclosing solution (Figure 17).
Step 3—apply coarse pumice in a rubber cup to all smooth surfaces.
Step 4—apply prophy jet to nonsmooth surfaces, being careful not to abrade gingival tissues.
Step 5—16x inspection of the dry, clean tooth, final microscopic plaque removal, apply caries indicator (Figure 18).
Figure 17
Disclosing solution demonstrates the incredible contamination present on an adolescent with seemingly excellent hygiene.
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Figure 18
After multiple deplaquing modalities, contamination remains. Long-term retention of any bonded material is impractical without a more aggressive approach. |
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Step 6—explore all microscopically suspicious defects with Fissurotomy Burs, alternating between 6x to 12x magnification. The goal of this step is to create a conical preparation that allows ideal visualization, superior enamel rod engagement and minimal dentin involvement.
A healthy debate is occasionally waged regarding ideal preparation design for the MDMIPC. For me, conservative dentistry has taken on a new meaning. The restoration that lasts longest and least predisposes the tooth to fracture is to me the most conservative because it conserves the tooth as an entity the longest. As we study initiation and propagation of tooth fractures² we see that the majority of incomplete fractures are oblique, not vertical. Most of these cracks initiate in dentin and not enamel, and nearly always follow the line angles of cavity preparations. We should reconfigure our value systems. It is dentin worship today, not enamel worship. The Fissurotomy Bur can make a much narrower cut in dentin than some of the parallel-sided cutting techniques that at first glance seem more conservative. More important than the cutting modality is microscopic visualization to remove minimum tooth structure and cut as shallowly as possible with the goal of not connecting the defects.
Step 7—reapply caries indicator. Although not foolproof, low-tech caries indicator still has benefits. Parents and patients who normally watch the live broadcast seem to appreciate this step that allows judicious and appropriate removal of tooth structure.
Step 8—final or repeated use of Fissurotomy Bur and caries indicator. When significant dentinal decay is discovered, Piranha Diamond #856-016 round-end tapered or a Great White #2 carbide is employed (SS White Burs, Inc). Fissurotomy Burs are not as aggressive as other diamonds or carbides at end cutting, which is a plus for ultraconservative groove and dogleg exploration. However, that makes them inefficient and risky in carious dentin, as excess force is required to end cut.
Step 9—finally, I do a careful 3-D observation at 16x or 24x of the walls of the preparation to look for lateral defects or caries (Figure 19). This is yet another moment when only microscopic visualization will do.
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Figure 19
Enamel defect is finally appropriately prepared with the Fissurotomy Bur. The newer bur can provide an even narrower preparation.
Step 10—apply etchant, utilizing liquid etch, then gel etch. A carefully prepared groove is so tiny that gel etch can be too viscous to reach the base; liquid etch helps to wet the enamel to facilitate the gel.
Two-step bonding, which allows a separate step for etching with phosphoric acid, offers an opportunity for incredible microscopic visualization. I find decay, chunks of old sealant, poorly etched sections, and a myriad of contaminations that seem to be only visible after application of etchant. |
Step 11—click in the microscope’s orange light filter, apply bonding resin, I prefer Optibond Solo (Kerr), which is lightly filled. Blow lightly with dedicated air syringe, do not light-cure, then apply flowable composite. Figures 14 to 16 demonstrate the futility of attempting to syringe the material directly into the microprep. I find that in many cases, it is best to apply near the prep and then tease it into the groove at 16x. If dentinal caries are removed, paste composite is added as another layer.
Step 12—bubble search at high magnification as seen in figure 16.
Step 13—light-cure, occlusal adjustment with a football shaped Piranha Diamond 379-023F and polish with a Jazz Supreme point (Figure 20).
Figure 20
MDMIPC at low (left) and high (right) magnification at 3-year follow up. Nine-year follow up at 16x in our practice shows 95% look good or excellent (treatment by Dr. Jihyon Kim).
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Summary
The original concept of dental sealants is truly intoxicating…that an entry-level auxiliary could prevent occlusal caries by painting over the grooves of the teeth, thereby freeing up the doctor for more difficult tasks…all with a tidy profit. The realities of high-level magnification and research are sobering the “sealant euphoria.” Today, we now understand that prevention of occlusal caries is significantly more complex and technically challenging than originally thought. Changing the process from a lower-skill, auxiliary-driven procedure to a high-skill, microscope-centered procedure will require a shift in scheduling and value systems.
Microscope-enhanced dentistry is much more than simply making tiny little holes in teeth. It is a commitment to dentistry where vision is un-compromised, and today that level can best be attained with an operating microscope.
References
1. Christensen RP, Ploeger BJ, Palmer TM. The role of pit-and-fissure discoloration in caries assessment. Compend Contin Educ Dent. Nov 2001;22(11A):996-1007.
2. Clark DJ, Sheets CG, Paquette JM. Definitive diagnosis of early enamel and dentin cracks based on microscopic evaluation. J Esthet Restor Dent. 2003; 15:391-401.
Dr. Clark is the founder and current president of the Academy of Microscope Enhanced Dentistry, an international association formed to advance the science and practice of microendodontics, microperiodontics, microprosthodontics, and microdentistry. He is a course director at the Newport Coast Oral Facial Institute and co-director of Precision Esthetics Northwest, both of which are nonprofit, microscope-centered teaching institutions. He has published a completely new approach to diagnosis and treatment of cracked teeth, based on a new nomenclature and classification system for enamel and dentinal cracks observed at 16x magnification. He provides video, still images, and support to Clinical Research Associates for its international presentations about the role of the clinical operating microscope in dentistry. He maintains a microscope-centered restorative practice in Tacoma, Wash, and can be reached at (253) 472-4292 or drclark@microscopedentistry.com. For more information, visit microscopedentistry.com, lifetimedentistry.net, and NCOFI.org.
