Real‐world titration, persistence & weight loss of semaglutide and tirzepatide in an academic obesity clinic

Data were obtained from the EHR and insurance claims repository at a single academic medical centre. Patients were identified by participation in the Medical Weight Loss Bundle program, and medical record numbers were used to link prescription fill data to corresponding EHR records. Data collection spanned from January 3, 2022, to February 25, 2025. The index date was defined as the date of the first GLP1RA prescription fill (semaglutide or tirzepatide), as indicated by the creation of a bill in the bundle clearing house. This study conforms with the recommendations of the STROBE guidelines for observational studies.13, 14

Data underwent standard quality checks for completeness and internal consistency. Records with missing or unmatched EHR‐claims linkage were excluded. Prescription‐filled data were validated against medication prescribing entries and pharmacy claims to confirm actual dispensing. Fill data were assumed to reflect active medication use unless evidence of medication discontinuation was documented in provider notes or billing claims.

This is a single‐centre, retrospective, observational study conducted at a multidisciplinary academic medical weight loss clinic. Patients were eligible for inclusion if they: (1) were aged 18–75 years, (2) were enrolled in the Medical Weight Loss Bundle insurance add‐on, and (3) had received at least one prescription for semaglutide or tirzepatide for the indication of obesity treatment.

The medical weight‐loss focused value‐based care bundle (MWLB) was developed to capture the total cost of care related to a comprehensive medical weight loss programme over a 12‐month period. Services included office visits with medical weight loss providers (physicians and advanced practice providers trained in Obesity Medicine), dietitians specialized in medical weight loss, weight‐loss focused mental health counsellors, access to exercise physiologists, dietary education materials, relevant laboratory and diagnostic testing, necessary specialty referrals, and all prescribed pharmaceuticals. Participants in the MWLB received these services without co‐pay or out‐of‐pocket expense. MWLB was made available for employers as a benefit for employees and their families. Of note, participating employers had gym benefits available for all employees. Employees and their families were not eligible for participation in the MWLB programme if they were actively participating in another value‐based care bundle (such as maternity or joint replacement bundles). Participants in this study were enrolled from January 3, 2022, through December 6, 2024.

Participants in the MWLB were recommended to follow a diet higher in protein (25%–30% of daily of calories), moderate in carbohydrates (40% daily calories), and lower in fat (30%–35% daily calories) split across three daily meals. Meal plans and daily caloric needs were tailored by dietitians to balance macronutrients and individual needs. Participants were offered a referral for a medical fitness evaluation within our institution and exercise prescription as per standardized recommendations for 150 minutes per week, which is encouraged.

Persistence was defined as continuous prescription fills without a gap exceeding three prescribing periods (defined as 28 days each). Adherence to the recommended titration schedule was assessed based on package insert guidance for semaglutide15 and tirzepatide,5 which recommend dose escalation every 4 weeks, with the goal of reaching the maximum recommended dose by the sixth prescription. Crossover between semaglutide and tirzepatide was considered continued persistence with GLP1RA therapy. Patients who unenrolled from the bundle during the study period were censored as non‐persistent due to loss of insurance coverage for GLP1RA and loss of subsequent prescription fill data. We stratified GLP1RA dosing into ‘low‐dose’ and ‘high‐dose’, using semaglutide <2 mg and tirzepatide <10 mg to define ‘low‐dose’.

Baseline demographic and clinical characteristics, including age, sex, race, ethnicity and pre‐existing comorbidities, were extracted from the EHR at the time of bundle enrollment. Comorbid conditions marked as resolved prior to enrollment were not considered active during the study period. Baseline weight was extracted using the closest in‐clinic recorded weight within 30 days of the index date. Implausible values (e.g., weight < 30 kg) were excluded. Percent total weight loss (%TWL) was calculated as. Baseline Weight Weight Timepoint Baseline Weight − / × at 100

The primary outcome was persistence with GLP1RA therapy. Secondary outcomes included: (1) adherence to recommended titration protocols, (2) maximum dose achieved, (3) transition between GLP1RA agents, (4) transitions from GLP1RAs to non‐GLP1RA anti‐obesity medications (AOMs), (5) weight change and variables associated with weight change during GLP1RA therapy, and (6) frequency and causes of emergency department (ED) visits and hospitalizations during the study period.

Gaps between prescriptions were permitted if a new prescription was filled within 30 days of the weight measurement. Attribution of ED visits and hospitalizations to medication use was determined based on diagnosis codes associated with each encounter and their consistency with known adverse effects of GLP1RAs. A full list of diagnosis codes used to classify these events is provided in Appendix. S1

Key covariates included age, sex, race/ethnicity, baseline weight, body mass index (BMI) and presence of comorbidities such as type 2 diabetes, hypertension, or dyslipidaemia. These will be adjusted for in multivariable models evaluating weight change and persistence outcomes. Planned subgroup analyses include comparisons between semaglutide and tirzepatide users, stratified analyses by sex and BMI class, and sensitivity analyses including patients with treatment gaps >84 days.

This study was approved by the Vanderbilt University Medical Center Institutional Review Board (IRB# 250171). A waiver of informed consent was granted due to the retrospective nature of the study and minimal risk involved. All data were de‐identified in compliance with HIPAA regulations.

Patient demographics, comorbidities, medication information and weight data were summarized using descriptive statistics. Percent total weight loss was compared between'low‐dos' and' high‐dos' groups at 3, 6, 9 and 12 months of persistent medication use using Wilcoxon Rank Sum tests. Linear mixed‐effects models were used to examine the trajectory of weight change over time while on medication. Fixed effects included age, sex, baseline weight, medication at 9 months, dose group at 9 months, and time since medication initiation, treated as a restricted cubic spline with three knots to account for potential non‐linearities in the effect of time. Interactions between dose group and medication, as well as between dose group and time since medication initiation, were included. A random intercept accounted for individual differences in baseline weight, and a random slope for time since medication initiation allowed the rate of weight change to vary across patients. Partial effects plots were used to visualize the relationships between key predictors and weight, and contrasts were applied to assess specific group differences. The analysis was restricted to patients with either a'low‐dos' or'high‐dos' at 9 months. Complete‐case analysis was performed. All statistical analyses were conducted using R version 4.2.2.

During the study period, 2855 patients were identified as having enrolled in the bundle, of whom 2306 (81%) received at least one prescription for semaglutide or tirzepatide. The median age of the cohort was 46 years (IQR 38–55 years), and 85% were female (Table 1). The cohort was predominantly White (68%), with 28% identifying as Black and 4% as other. Only 4% identified as Hispanic. The most common baseline comorbidities were hypertension (43%), followed by osteoarthritis (32%) and gastroesophageal reflux (28%). Thirteen percent had pre‐existing type 2 diabetes.

The vast majority of patients (92%) initiated semaglutide as the first medication after enrolling in the bundle (Table 2). Consequently, 70% of patients received semaglutide exclusively, 5% received tirzepatide only and 25% received both medications at different times. Patients received a median of 12 prescriptions (IQR 6–17) and a median of 3 (IQR 2–5) unique prescriptions (i.e., either new dose or drug change). Using a 3‐supply gap (84 days) to define discontinuation, the median duration of use within the cohort was 10.7 months (IQR 5.4–16.3). Medication discontinuation was 14%, 24%, 35% and 50% at 3, 6, 9 and 12 months, respectively. Only 9.1% of patients were using a non‐GLP1RA AOM prior to starting semaglutide or tirzepatide, and only 5.7% newly initiated a non‐GLP1RA AOM after discontinuing either semaglutide or tirzepatide.

Transitions between doses of semaglutide and tirzepatide are illustrated in the Sankey diagram in Figure 1A,B, respectively. Of the 2189 patients who received semaglutide, 93% of patients initiated on 0.25 mg or 0.25/0.5 mg starter pack. By the 6th prescription, 24% were receiving 2 mg or more, and 12% received 2.4 mg of semaglutide. For the 692 who received tirzepatide, likely owing to switching between GLP1RAs, 48% of patients initiated at 10 mg or higher, while 28% initiated on 2.5 mg. By the 6th prescription, 63% of participants received 10 mg or higher, and 18% received 15 mg of tirzepatide; 81% of patients received one prescription of ≥1 mg and 55% received ≥2 mg of semaglutide; 75% of patients received at least one prescription of ≥10 mg of tirzepatide, while 28% received 15 mg.

Medication switches were common among the group, with 575 (25%) using both semaglutide and tirzepatide at different points of the study period. In total, 18% had 1 medication switch, and 5% switched twice (Figure 2). The most common transitions were semaglutide 2 mg to tirzepatide 10 mg (135 patients, 23%), followed by semaglutide 2 mg to tirzepatide 12.5 mg (101 patients, 18%), and semaglutide 1 mg to tirzepatide 7.5 mg (69 patients, 12%).

At least one emergency room visit and hospitalization related to medication occurred in 13.6% of the overall cohort. The most common reason for ER visits and hospitalizations in this cohort was for GI disorders (8.6% of visits) which include gastroesophageal reflux, constipation and gastroenteritis, followed by abdominal pain (2.4% of visits), and nausea, dehydration and nutritional issues (2.3%). Hepatobiliary‐related complications were rare (0.2% of visits), and one visit for acute pancreatitis was identified.

For patients with at least 3 months of persistent GLP1RA use, %TWL was 5.5% (IQR 3.0–8.0%). For those with 6 months persistent use, %TWL was 9.4% (IQR 6.0–13.4%); for 9 months, %TWL was 12.9% (IQR 8.4–17.1); and for 12 months persistent use, %TWL was 14.4% (9.5–20.5%). When comparing those who achieved a ‘low‐dose’, or ‘high‐dose’ of semaglutide or tirzepatide at specific time points, on univariate analysis we found no difference in %TWL between those receiving low‐ or high‐dose semaglutide or tirzepatide at 6, 9 and 12 months of persistent use (p = 0.3, 0.6, and 0.8, respectively).

We also evaluated patients who used only a single GLP1RA (i.e., did not switch GLP1RAs). For patients who received semaglutide exclusively (N = 1614), %TWL was 5.7% [IQR 3.2–8.0], 9.8% [IQR 6.4–13.6], 13.5% [IQR 9.0–18.4], and 15.6% [10.8–21.9] at 3, 6, 9 and 12 months respectively. Follow‐up rate at each time‐point for semaglutide users was 62%, 47%, 37% and 29%, respectively. For those who received tirzepatide exclusively (N = 117), %TWL was 7.1% [4.4–9.7], 11.9% [7.6–16.6], 16.3% [12.0–22.3], and 14.1 % [9.9–22.1] at 3, 6, 9 and 12 months, respectively. Follow‐up rate at each time‐point for tirzepatide users was 63%, 56%, 40% and 14% respectively.

Weight loss appeared to be maintained with a percent change in weight of 0.3% and 0.1% at 3 and 6 months post‐GLP1RA, respectively, although missingness was high for weight data after discontinuation (>65% for both timepoints). For patients remaining on medication at given timepoints, missingness of weight data was 19%, 22%, 20% and 14% at 3, 6, 9 and 12 months, respectively, and 36.8% lacked weight data within 30 days of medication discontinuation.

In multivariable linear mixed‐effects models examining weight over time among patients with dose information at 9 monthspost‐drug initiation, weight decreased significantly over time (p < 0.001). Male sex was associated with an estimated 0.89 kg lower weight compared with females (95% CI −1.46 to −0.33, p = 0.002), and higher baseline weight was associated with higher weight across follow‐up (estimate: 0.98 kg; 95% CI 0.97–0.99, p < 0.001). The interaction between high‐dose treatment and time since medication initiation was significant (p < 0.001), indicating that patients on high‐dose regimens by 9 months experienced greater initial weight loss, though the rate of loss slowed over time (Figure 3). Model‐estimated contrasts indicated that high‐dose users at 9 months experienced greater total weight loss compared with low‐dose users, with estimated losses of 14.7 kg (95% CI 14.1–15.3) versus 13.6 kg (95% CI 12.9–14.3) per year, respectively. This difference of 1.1 kg was statistically significant (p = 0.020). The interaction between high‐dose treatment and time since medication initiation was significant (p < 0.001), indicating that patients on high‐dose regimens by 9 months experienced greater initial weight loss, though the rate of loss slowed over time (Figure 3). Model‐estimated contrasts indicated that high‐dose users at 9 months experienced greater total weight loss compared with low‐dose users, with estimated losses of 14.7 kg (95% CI 14.1–15.3) versus 13.6 kg (95% CI 12.9–14.3) per year, respectively. This difference of 1.1 kg was statistically significant (p = 0.020).

The data that support the findings of this study are available on request from the corresponding author. The data are not publicly available due to privacy or ethical restrictions.