Comparative analysis of Decision Trees, Random Forest, and Multilayer Perceptron algorithms for no-show prediction in dental healthcare settings

For dental office managers, owners, and IT staff, patient no-shows mean lost time and money. When patients miss appointments without notice, the office cannot fill those slots with other patients. This causes staff to be idle and resources to go unused. Over time, frequent no-shows lower the clinic’s efficiency and make other patients wait longer, which frustrates everyone involved.

Studies show that no-shows happen worldwide for many reasons, like forgetfulness, troubles with transportation, or changes in patient plans. In the United States, where people are busy and dental care access varies, this problem gets bigger. Predicting who might not show up helps clinics plan better, like booking extra patients or sending reminders. This reduces wasted time and helps more people get dental care.

Machine Learning Algorithms for No-Show Prediction

Researchers Taghreed H. Almutairi and Sunday O. Olatunji did a study in dental clinics in Saudi Arabia using three machine learning models: Decision Trees, Random Forest, and Multilayer Perceptron. Although their work was outside the United States, it still applies to U.S. dental clinics because of similar challenges.

The models were trained using data from five dental clinics covering nine different dental fields. They included factors that affect patient behavior and whether they attend appointments. The study also used explainable AI methods to show how these factors affected the predictions, making the results easier to understand.

Decision Trees Algorithm

Decision Trees are a type of machine learning that looks like a tree of choices and outcomes. They are simpler than some other methods but easy to understand, which is useful in healthcare.

In the study, the Decision Tree model reached:

• 79% precision: It correctly predicted 79% of patients who would not show up.
• 94% recall: It found 94% of all real no-shows.
• 86% F1-Score: A measure that balances precision and recall, showing good accuracy.
• 84% AUC: How well the model tells no-shows apart from attendances.

High recall is important because missing a predicted no-show means losing a chance to fill that slot with someone else.

For U.S. dental clinics, Decision Trees are helpful because staff can see the rules behind predictions. This helps them understand what causes no-shows and makes it easier to create solutions like reminder calls or transportation help.

Random Forest Algorithm

Random Forest combines many Decision Trees and uses their results together. This helps make better predictions and avoid mistakes from one tree alone. It works well with lots of data and different factors.

The Random Forest model showed:

• 81% precision: Slightly better than Decision Trees.
• 93% recall: Almost as good at finding no-shows.
• 87% F1-Score: Better overall performance than Decision Trees.
• 83% AUC: Similar ability to tell no-shows from attendances.

In the U.S., this model offers reliable no-show predictions. Though it works more like a “black box,” explainable AI used in the study helps show which factors matter most. This lets clinics design personalized ways to reduce missed appointments.

Random Forest works well in big clinics or dental groups where patient types and appointments are very different.

Multilayer Perceptron Algorithm

The Multilayer Perceptron (MLP) is a type of neural network inspired by how the brain works. It can find complicated patterns in data. This was the first time MLP was tried for predicting dental no-shows in this study.

The MLP model results were:

• 80% precision: Better than Decision Trees but not as good as Random Forest.
• 91% recall: Lower than the other two models.
• 86% F1-Score: Similar balanced accuracy to Decision Trees.
• 83% AUC: About the same as Random Forest.

MLP is less transparent than Decision Trees but offers a new method for these predictions. Clinics with stronger IT systems or tech partners can use MLP to improve no-show forecasts.

Key Factors Influencing No-Shows and Explainable AI

The study also used Explainable AI to show why the models made certain predictions. This helped point out important reasons why patients missed appointments.

Knowing these reasons lets U.S. dental offices handle root problems, like money issues or transportation troubles, instead of just reacting after patients miss visits. For example, if transportation is a big issue, clinics might work with ride-share companies or offer remote dental care when possible.

Application to U.S. Dental Healthcare Settings

Dental clinics in the United States see more patients and also face problems like no-shows. The need to manage appointments well will keep growing. Using machine learning models proven in research can help improve operations.

Each model has its strengths:

• Decision Trees: Easy to understand and use.
• Random Forest: More accurate and reliable.
• Multilayer Perceptron: Finds complex patterns for clinics with strong IT support.

Choosing a model depends on the clinic’s size, technology, and resources for patient communication.

Integration of AI with Workflow Automations: Streamlining Dental Clinic Operations

Predicting no-shows is only part of the solution. Combining AI with automation can improve dental clinic work in the United States.

Automation tools can handle tasks like reminding patients or rescheduling without needing much staff time. Examples include:

• Automatic calls or texts triggered by AI predictions to reach patients likely to miss appointments.
• AI answering calls and confirming appointments to reduce missed communication.
• Booking extra patients when AI expects some no-shows to keep schedules full.
• Dashboards that show appointment updates in real time for quick action by staff.

This combined approach helps managers and IT teams lower their workload, improve patient contact, and increase clinic earnings.

Practical Considerations for U.S. Medical Practice Administrators and IT Managers

Choosing AI models requires good patient and appointment data. The Saudi Arabian study used data from many dental fields, so U.S. clinics should also collect enough useful information.

Using AI needs teamwork between office staff, dental providers, and IT. Training is needed so everyone can handle AI tools and understand the results.

Patient privacy and following HIPAA rules are very important. AI systems must keep data safe with strong security and encryption.

Patient no-shows are a challenge for U.S. dental clinics that newer AI methods like Decision Trees, Random Forest, and Multilayer Perceptron can help address. When clinics pick the best model for their situation and add workflow automation, they can reduce missed appointments, improve patient care, and run more smoothly.

Clinic managers, owners, and IT staff who want to improve efficiency should think about using these AI tools as part of their plans for future dental care.