Figures
Abstract
Background
For biopharmaceutical companies, investments in research and development are risky, and the results from clinical trials are key inflection points in the process. Few studies have explored how and to what extent the public equity market values clinical trial results.
Methods
Our study dataset matched announcements of clinical trial results for investigational compounds from January 2011 to May 2013 with daily stock market returns of large United States-listed pharmaceutical and biotechnology companies. Event study methodology was used to examine the relationship between clinical research events and changes in stock returns.
Results
We identified public announcements for clinical trials of 24 investigational compounds, including 16 (67%) positive and 8 (33%) negative events. The majority of announcements were for Phase 3 clinical trials (N = 13, 54%), and for oncologic (N = 7, 29%) and neurologic (N = 6, 24%) indications. The median cumulative abnormal returns on the day of the announcement were 0.8% (95% confidence interval [CI]: –2.3, 13.4%; P = 0.02) for positive events and –2.0% (95% CI: –9.1, 0.7%; P = 0.04) for negative events, with statistically significant differences from zero. In the day immediately following the announcement, firms with positive events were associated with stock price corrections, with median cumulative abnormal returns falling to 0.4% (95% CI: –3.8, 12.3%; P = 0.33). For firms with negative announcements, the median cumulative abnormal returns were –1.7% (95% CI: –9.5, 1.0%; P = 0.03), and remained significantly negative over the two day event window. The magnitude of abnormal returns did not differ statistically by indication, by trial phase, or between biotechnology and pharmaceutical firms.
Conclusions
The release of clinical trial results is an economically significant event and has meaningful effects on market value for large biopharmaceutical companies. Stock return underperformance due to negative events is greater in magnitude and persists longer than abnormal returns due to positive events, suggesting asymmetric market reactions.
Citation: Hwang TJ (2013) Stock Market Returns and Clinical Trial Results of Investigational Compounds: An Event Study Analysis of Large Biopharmaceutical Companies. PLoS ONE 8(8): e71966. https://doi.org/10.1371/journal.pone.0071966
Editor: Eshel Ben-Jacob, Tel Aviv University, Israel
Received: June 6, 2013; Accepted: July 8, 2013; Published: August 7, 2013
Copyright: © 2013 Thomas J. Hwang. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: TJH was supported by the Cordeiro Research Fellowship of the Interfaculty Initiative in Health Policy and a research grant from the Center for American Political Studies, both at Harvard University. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The author has declared that no competing interests exist.
Introduction
Research and development (R&D) is a hallmark of innovative biopharmaceutical companies. The stakes for these R&D activities are high due not only to their contribution to firm profitability and competitiveness but also to their role in potentially relieving suffering and curing sickness.
A number of industry commentators have argued that the biopharmaceutical industry faces a R&D ‘productivity crisis.’ [1], [2] There is some evidence to suggest that development risks, which refer to the likelihood that the R&D process will be terminated due to safety, efficacy, or commercial concerns, remain high. [3], [4], [5] Late-stage clinical studies (Phase 2–3) are also the most expensive stage of the drug development process, making attrition during this stage particularly problematic for management and investors. [6], [7] The costs of Phase 3 trials alone are estimated to account for up to 40% of total R&D costs. [8].
Given the risks, uncertainty, and difficulty associated with developing new medicines, the release of clinical trial results is an important and closely anticipated inflection point in the R&D lifecycle. As the stock price of a firm represents an assessment of its current and future earnings capacity, these announcements are expected to have positive or negative effects on the firm’s market valuation. There has been increasing attention paid by the medical and scientific communities to this and other measures of the financial performance of biopharmaceutical companies. For example, some have suggested that prescribers could monitor stock prices to ascertain early warnings about drug safety. [9] Some physicians and scientists are also involved in a range of financial activities, ranging from consulting and investment advice to employment by brokerages and hedge funds to personal trading. [10] Expert knowledge of clinical trials can be lucrative, [11], [12] and the potential for insider trading is an ever-present risk. [13].
Previous research on R&D and market valuation has largely focused on capital expenditures or product development outcomes, such as drug approvals and patents. Some have observed positive share price responses to increased R&D spending despite lower earnings. [14] Others have found that financial market losses from product development failures are larger in magnitude than gains from successes. [15], [16] There has been limited empirical work examining how and to what extent the stock market values measures of R&D, such as clinical trials, for investigational compounds. A pair of studies, one on oncology drugs [17] and another on biotechnology products [18], found that there are measurable changes in company stock prices before important trial announcements and significant differences in stock price changes between companies with a successful product versus those with an unsuccessful product.
The primary aim of this study was to investigate the impact of unforeseen clinical research results on stock market returns for biopharmaceutical companies that obtain capital through the public equity market, i.e. publicly traded companies. To measure the market value effects of our sample of clinical R&D events, we used event study methodology, which is widely used in financial economics to measure abnormal returns from a given stock after adjusting for normal market performance [19], [20] though its application to the clinical-scientific literature is relatively new. [21], [22] Specifically, we proposed using a short horizon event study, narrowing the time period of analysis to two days before and after an event, to isolate the market reaction to that event. Therefore, barring confounding events, this method captures the natural experiment that occurs in stock returns due to new information, and more accurately accounts for financial performance than changes in stock prices alone. We defined the following hypotheses relating to the public market’s valuation of and reaction to clinical development events:
H1 (Null): There is no difference between abnormal stock market returns immediately before or after announcements of clinical trial results and zero.
H1.1 (Alternative): Positive development events are associated with significant and positive share price changes.
H1.2 (Alternative): Negative development events are associated with significant and negative share price changes.
H2 (Null): There are no differences in abnormal stock market returns due to positive versus negative announcements.
H2 (Alternative): The abnormal stock market returns due to negative announcements are significantly larger than those for positive events.
Methods
Sample Selection
Our event study focused on the R&D activities of large publicly traded biopharmaceutical companies in the U.S. from January 1, 2011 to May 1, 2013. A ‘large biopharmaceutical company’ was defined as a biotechnology or pharmaceutical company with revenues from branded pharmaceutical products, such as drugs and biologics, representing at least 50% of total gross revenues and in excess of US$5 billion, as of 2012. Descriptive statistics of the seven firms meeting these criteria are provided in Table 1.
Data Collection and Extraction
For our sample of firms, we searched Factiva for news articles and public announcements of results from Phase 1, 2, and 3 trials of investigational compounds. The key words for the search included: ‘clinical trials,’ ‘studies,’ ‘research,’ ‘Phase 1,’ ‘Phase 2,’ ‘Phase 3,’ ‘science,’ and ‘scientific evidence.’ We included the first announcement that signaled a positive or negative result, and excluded announcements for studies of compounds that had been approved by the U.S. Food and Drug Administration (FDA) or European Medicines Agency (EMA) as of May 1, 2013. We also manually collected and reviewed press releases, transcripts of quarterly earnings calls, and other public statements from company websites. Additional identified announcements were merged with our search results, following exclusion of non-relevant or duplicate citations.
Data on study characteristics, outcome measures, and results were extracted from the announcements in our merged search results using a pre-defined extraction form. This form captured: company, publication date, phase of trial, study design, observation period, number of patients treated, number and type of treatment arms, investigational compound used, indication(s), primary and secondary endpoints, whether results were interim (or ‘top-line’) or final, whether the primary and/or secondary endpoint(s) were met, and whether the data were (or due to be) presented at a conference or published in a peer-reviewed journal. Based on the extracted data, the announcements were ordered chronologically and assigned a priori expected signs. An announcement was coded as positive if the firm reported meeting the primary endpoint or, in the case of interim results, efficacy or safety data meriting the firm’s regulatory submission or initiating the next stage of clinical development. Negative events involved results failing to meet pre-specified outcome measures and discontinuations of studies due to safety, efficacy, or other reasons. The coding of expected signs was validated by review of the original text.
Event Study Methodology
The standard short horizon event study methodology for market-adjusted residual returns relies on the assumption of efficient capital markets—that is, stock prices reflect the continuum of new information received and processed by market participants. As all of the firms in our sample are large and listed primarily on U.S. stock exchanges, we did not have to account for thin market trading volumes or other possible violations of event study assumptions.
First, we defined the event window as two and one trading days before and after the event date, defined as day 0, and reference window as 300 trading days (–310 to –10) before the date. Reference windows of similar length have been used widely in the literature. [21]–[22] To reduce the likelihood of confounding events and bias, we excluded events in our sample with overlapping ± 2 day windows with material firm-level events. Potentially confounding events included: other announcements in our sample; regulatory, legal, financial (e.g. mergers and acquisitions, licensing agreements, etc.) and corporate management (e.g. resignations) decisions; and announcements for studies of approved products.
For each firm i at time t during the estimation window, the coefficients α and β of the market model were estimated by OLS using stock price data from Bloomberg Professional. Formally, the estimation equation is:(1)
where Rit is the stock return and RMt is the normal market return. The value of the S&P 500 stock index was used as the market portfolio.
Next, we calculated the daily abnormal return (ARit) by comparing the stock return at time t during the event window to the expected market return if the event had not occurred:(2)
Finally, cumulative abnormal returns (CAR) during the event window (t1, t2) are given by:(3)
Firm-level and aggregate CAR were calculated for the time-symmetric (–2, +2) and (–1, +1) windows. To examine the immediate effects of the announcement on stock returns and to account for potential information leakage and/or latecomers to the event, we also calculated CAR for the periods (–2, 0), (–1, 0), and (–2, +1). For these five sub-windows, we also calculated the proportions of events with the same signs (positive or negative) as expected.
Statistical and Sensitivity Analyses
Given the small sample size, we used the nonparametric one-sample Wilcoxon signed-rank test to test the null hypothesis that the median CAR for a given window is equal to zero. The Wilcoxon signed-rank test considers both the sign and magnitude of abnormal returns and does not assume normality or infer the value of any population parameter. This approach, though less common in the literature than parametric t statistic tests, has been documented to be preferable to other test methods with respect to event clustering, increases in variance on the event day, and Type I errors (or the incorrect rejection of null hypotheses). [23], [24], [25], [26] To compare the proportion of CAR signs at different times during the event window, we also used the binomial test.
As a measure of the robustness of our results, we conducted sensitivity analyses using a shorter estimation reference window of 30 trading days before and after the announcement date. The Mann-Whitney-Wilcoxon test was used to compare abnormal returns by firm type (biotech vs. pharmaceutical), proportion of R&D spending relative to total revenues, market capitalization, indication, and trial phase. We also used regression models with and without bootstrap resampling to test for potential interactive effects. Statistical analyses were performed using Stata (version 12.0, Stata Corp, College Station, TX, USA), with a two-sided α = .05.
Results
Our sample comprised 24 public results announcements relating to 23 clinical trials registered on ClinicalTrials.gov (Figure 1) and 24 unique investigational compounds. Two articles reported data on different combination regimens from a multipart Phase 2 trial of sofosbuvir (GS-7977) and ribavirin in hepatitis C genotype 1 patients. Table 2 shows the characteristics of our sample events. Of the 24 events, 16 (67%) were positive and eight (33%) were negative. Five (31%) of the positive announcements were for Phase 3 clinical trials, nine (56%) for Phase 2, and two (13%) for Phase 1. All of the negative announcements were for Phase 3 trials. There were an equal number of announcements from large pharmaceutical companies compared with biotechnology companies. Most of the selected events were for oncologic (N = 7, 29%) and neurologic (N = 6, 24%) indications. There were an additional three trials for hepatitis C, two for diabetes and hypertension, two for psoriasis, one on hemophilia B, one on HIV, one on rheumatoid arthritis, and one on ragweed allergies. Nine (38%) compounds were biologics.
Stock Returns Analysis
All positive events were associated with stock price increases during the ± 1 and ± 2 trading day event windows, whereas negative events were associated with stock price decreases. In the majority of cases, the sign of the cumulative abnormal returns (CAR) ± 2 days matched the expected a priori sign (Figure 2). For positive announcements, the CARs for 12/16 events were positive by market close of the day of the announcement, compared with 8/16 two trading days prior. There were a modest number of CAR sign reversals on the day after, with 9/16 events with positive CARs, though the difference in proportions was not statistically significant (P = 0.09). For negative announcements, the proportion of events with negative CARs increased steadily from –2 days to the day of the announcement. The proportion of events with negative CARs was significantly greater on day 0, +1, and +2 compared with –2 (P = 0.004).
Notes: Panel A shows the proportion of CAR due to positive events with positive (blue) and negative (red) signs during the ± 2 trading day window. Panel B shows the proportions for negative events. Panel C displays the proportion of events with the same actual and expected CAR sign for the entire sample.
Figure 3 depicts the median CARs for positive and negative announcements along the ± 2 day event window. The absolute value of CAR was greatest on the day of the announcement (–2, 0) for both positive and negative events. The median CAR (–2, 0) for positive events was 0.8% (95% confidence interval [CI]: –2.3, 13.4%), and the increase in CAR was statistically significant (P = 0.02). The median CAR for (–2, +1) and (–2, +2) remained positive, at 0.4% (95% CI: –3.8, 12.3%) and 0.8% (95% CI: –3.9, 12.2%) respectively, though the differences were not statistically significant (P = 0.33). For negative events, the median CAR (–2, 0) was –2.0% (95% CI: –9.1, 0.7%), which was statistically significant (P = 0.04). The median CAR for (–2, +1) and (–2, +2) were –1.7% (95% CI: –9.5, 1.0%; P = 0.03) and –1.2% (95% CI: –10.0, 1.0%; P = 0.04), respectively.
Note: Median CAR during the ± 2 trading day window are shown for positive (blue) and negative (red) events.
To account for the possibility of information leakage, we also analyzed abnormal returns from a shorter window of ± 1 day relative to the date of announcement (Figure 4). Over the window (–1, 0), the median CARs were 0.9% (95% CI: –2.8, 13.5%; P = 0.02) and –0.7% (95% CI: –8.2, –0.02%; P = 0.01) for positive and negative events, respectively. Over the entire ± 1 day window, the CAR for positive events failed to reach statistical significance (median: 0.5%; P = 0.28). The median CAR (–1, +1) for negative events was –1.3% (95% CI: –9.1, 0.6%; P = 0.04).
Note: Median CAR during ± 1 trading day window shown for positive (blue) and negative (red) events.
Sensitivity Analysis
Our results were robust to the use of an estimation period of thirty trading days before and after the event rather than three hundred preceding trading days (Figure S1). With the shorter reference window, the median CAR (–2, 0) for positive events was 0.7% (95% CI: –1.5, 13.5%; P = 0.02) and –1.4% (95% CI: –6.6, 1.0%; P = 0.09) for negative events. Over the entire ± 2 day window, significant CAR persisted for negative events (median: –1.4%; P = 0.04) but not for positive events (median: 0.6%; P = 0.20).
For both positive and negative events, there were no significant differences in CAR over the ± 2 day window between late-stage (Phase 3) and early-stage (Phase 2 and 1) announcements, between biotechnology and pharmaceutical firms, or by indication or trial phase. In a multiple regression stratified by event type with and without bootstrap resampling, these variables were not significant predictors of CAR.
Discussion
In this paper, we evaluated the impact of R&D announcements on the financial performance of large U.S. biopharmaceutical companies, using event study methodology to link a novel dataset of results from clinical trials of investigational compounds with daily stock market returns. We found that both positive and negative announcements resulted in statistically significant changes in cumulative abnormal returns on the day of the announcement. The median decline in cumulative abnormal returns due to negative events was larger in magnitude than gains due to positive events, therefore rejecting our null hypotheses. We also found that the CAR due to negative announcements remained significantly negative through the entire two day window, whereas positive events were associated with stock price corrections the day after the event. Abnormal returns due to positive or negative announcements did not differ by indication, phase, or firm type (biotech versus pharmaceutical). In a post hoc sensitivity analysis, our results were robust to an alternative reference window.
Our results indicate that clinical development events have material economic implications, even for large biopharmaceutical companies with multidrug portfolios, and provide insight into the short-term behavior of the market in response to trial results. These findings confirm and extend previous scholarship on the significant market reactions to clinical trial results for biotechnology companies with few compounds in development. Moreover, this study contributes to the broader scholarship on the interplay between information and the financial markets, stemming largely from Cutler et al.’s seminal paper in 1989. [27]–[34] Recent studies have suggested trading behavior in response to news varies by investor type [35] and have examined the effects of alternate sources of news, such as Google and Yahoo! search volumes [36]–[38], Wikipedia usage [39], and Twitter mood [40], on stock returns and investor behavior. A comprehensive study of nearly 25 million news records revealed that news flows partially explain financial market volatility [41], though others have suggested a more minor role of news [42]. Intriguingly, our results showing a steeper and sustained decline in stock returns, after adjusting for normal market performance, as a result of negative announcements versus positive announcements suggest that the market may react asymmetrically to clinical R&D news.
There are several possible explanations for this asymmetry. Previous studies have found that the market reacts disproportionately unfavorably to product development failures than successes, and our abnormal returns analysis may lend credence to this behavior. One hypothesis is that negative announcements leave an imprint on investor perceptions of the company or confidence in the ability of senior management to conduct well-run clinical trials—that is, negative events may have a ‘reputational’ effect. [43] One could speculate that the market incorporates this ‘reputational’ component implicitly and explicitly into its valuation calculus, though a reputational cost per se stands in contrast to what may be expected by the efficient market hypothesis: market participants will and do make unemotional calculations of asset valuation. Alternately, one could argue that as the results of clinical trials are anticipated events, market participants have already factored risk-adjusted expectations about their outcomes into the stock price. Therefore, absolute differences in abnormal returns may arise due to varying probabilities for success or failure, levels of uncertainty, risk-taking, or some combination thereof.
Our study has several limitations. First, we analyzed events and market responses relating to large publicly traded U.S. pharmaceutical and biotechnology companies; as such, our results may not be generalizable to smaller biotech companies, though one could suspect that smaller companies dependent on a handful of drugs will be subject to larger fluctuations in stock price, or non-U.S. firms. Second, there are a number of issues that arise in treatment of small sample sizes. To mitigate potential bias and risk of Type I errors, we used nonparametric tests and bootstrap resampling accordingly. However, our sample was not sufficiently powered—or designed—to measure the effects of multiple predictors, and the interactions of those variables, on abnormal returns. Finally, while we sought to account for firm-level overlap in event windows, external and competitor events may have also influenced firm results. For example, there may be spillover or contagion effects from events that do not immediately relate to a firm’s R&D activities. [44], [45] Indeed, stock prices are better understood as multifactorial constructs, though the use of a short horizon is a clean method that controls some, if not most, of these potential confounding factors.
Despite these limitations, our findings are robust to a battery of sensitivity analyses, indicating that biomedical research is indeed a value driver for biopharmaceutical companies and that the results of this research are interpreted asymmetrically by the market. Although our results do not, at first glance, show detectable insider trading before positive or negative announcements, the potential for illicit transfers of information on clinical trial results remains a challenge for regulators and policymakers. Recently, a former executive of the hedge fund SAC Capital Advisors faced charges due to stock trades allegedly made on tips from clinical investigators on the results of an Alzheimer’s disease clinical trial. [46] Since 2007, nearly 100 people have been charged or sued by regulators for insider trading on internal results relating to drugs and devices, and more than one in five US insider trading cases involve healthcare stocks. [47] Further research expanding our sample and on the behavioral implications of asymmetric market valuations of R&D efforts would be warranted.
Public equity markets are often a vital source of capital for biopharmaceutical companies that invest in the costly process of research and development for novel, and potentially lifesaving, therapeutics. To the extent that access to capital and therefore market valuation of R&D efforts shape the course of scientific innovation, a better understanding of how markets react to clinical development events is needed.
Supporting Information
Figure S1.
Median CAR (–2, t) for positive and negative events using (–30, +30) reference window (robustness check). Note: The median CAR calculated at different times along the ± 2 trading day window are shown for positive (blue) and negative (red) events.
https://doi.org/10.1371/journal.pone.0071966.s001
(PDF)
Acknowledgments
The author thanks Richard Freeman and Giuliano Bianchi for insightful discussions and two anonymous reviewers for valuable feedback on earlier versions of this manuscript.
Author Contributions
Conceived and designed the experiments: TJH. Performed the experiments: TJH. Analyzed the data: TJH. Wrote the paper: TJH.
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