4Journal of MarketingVol. 73 (July 2009), 4–30
© 2009, American Marketing AssociationISSN: 0022-2429 (print), 1547-7185 (electronic)
Stefan Stremersch & Walter Van Dyck
Marketing of the Life Sciences:A New Framework and Research
Agenda for a Nascent FieldAlthough marketing scholars often seek to contribute new knowledge that is applicable across industries, someindustries have unique characteristics that require industry-specific knowledge development. The authors arguethat this requirement applies to the life sciences industry, defined as companies in pharmaceuticals, biotechnology,and therapeutic medical devices. Marketers in the life sciences industry face novel and unique challenges alongeight decision areas in therapy creation, therapy launch, and therapy promotion. In therapy creation, they facetherapy pipeline optimization, innovation alliance formation, and therapy positioning decisions. In therapy launch,they face global market entry timing and key opinion leader selection decisions. Therapy promotion mostly revolvesaround sales force management, communication management, and stimulating patient compliance. The authorsqualify these decision areas according to their practical importance and academic potential. The article derivespreliminary generalizations and propositions from prior research and practice and steers further research in specificdirections. The authors believe that marketing of the life sciences offers a fertile area for further research because,among other things, its potential impact transcends any problems typically investigated by marketing scholars.
Keywords: life sciences, marketing theory, research agenda, pharmaceutical, biotechnology, medical device,marketing, sales
Stefan Stremersch is Chaired Professor of Marketing and DesideriusErasmus Distinguished Chair of Economics, Erasmus School of Econom-ics, Erasmus University Rotterdam, and Visiting Professor of Marketing,IESE Business School, Universidad de Navarra, Barcelona (e-mail:[email protected]). Walter Van Dyck is Associate Professor of Tech-nology and Innovation Management, TiasNimbas Business School,Tilburg University and Eindhoven University of Technology (e-mail:[email protected]). The article was written when the secondauthor was on the faculty at Erasmus University, and both authors con-tributed equally to this article. The authors acknowledge the researchassistance of Christiaan Bakker, Christian Van Someren, and Jo Sinjorgo.They also thank Jacco Keja from Quintiles and Servaas Buijs from IMSHealth, both business partners of the Institute for Life Sciences BusinessEconomics at Erasmus University Rotterdam, for their support. They aregrateful for the comments on preliminary versions of this article by theircolleagues Nuno Camacho, Eelco Kappe, Vardit Landsman-Schwartz,Isabel Verniers, Sonja Wendel, and Stefan Wuyts. Finally, they thank sur-vey respondents in the business and academic communities, as well asthe anonymous JM review team, for their valuable suggestions.
Although marketing scholars often seek to contributenew knowledge that is applicable across industries(Stewart 2002), some industries have unique charac-
teristics that require industry-specific knowledge develop-ment (Eliashberg, Elberse, and Leenders 2006). Examplesinclude the services industry (Parasuraman, Zeithaml, andBerry 1985; Rust and Chung 2006; Vargo and Lusch 2004),the entertainment industry (Eliashberg, Elberse, and Leen-ders 2006; Eliashberg and Shugan 1997), and the high-techindustry (Bourgeois and Eisenhardt 1988; Glazer and Weiss1993; Heide and Weiss 1995; John, Weiss, and Dutta 1999;Stremersch et al. 2007; Weiss and Heide 1993).
In this article, we argue that this requirement alsoapplies to the life sciences industry. In our definition, this
industry spans companies in pharmaceuticals, biotechnol-ogy, and therapeutic medical devices, and it forms the inno-vative producer side of the health care industry. Two funda-mental dimensions underlie the life sciences industry:science-based knowledge (know-why) and quality of life.
Life sciences companies are significantly more linked toscience than any other industry and convert the know-whythey develop into new therapies (therapy creation). Theresultant therapy is launched into society only after scien-tific review of its impact on people’s quality of life throughexamination of the therapy’s safety, efficacy, and incremen-tal cost effectiveness (therapy launch). Life sciences firmspromote their life sciences therapies to both health careproviders and patients within the regulatory frameworkdesigned by society (therapy promotion). Marketers faceunique challenges in therapy creation, therapy launch, andtherapy promotion decisions (see Figure 1).
The scant survival probability of newly created thera-peutic inventions—only 1 in 5000–10,000 new inventionseventually makes it to market—leads to life sciences devel-opment portfolios being uniquely shaped as funnels (Dingand Eliashberg 2002). Life sciences marketers decide ontherapy positioning—the match between indication and newtherapy—many years before market entry. Market entry fornew therapies is strictly regulated, differentially so acrosscountries. If market access is granted, manufacturers get alimited time—in most cases, 20 years as of initial applica-tion filing, 10–12 of which are typically spent in clinicaldevelopment—of market exclusivity, after which generictherapies can enter the market. Life sciences firms’ market-ing efforts are typically capped (e.g., in many Europeancountries) and/or regulated (e.g., some states in the UnitedStates require medical sales representatives to undergo a
Marketing of the Life Sciences / 5
Therapy Creation
•Therapy pipelineoptimization
•Innovation allianceformation
•Therapy positioning
Therapy Launch
•Global market entrytiming
•Key opinion leaderselection
Therapy Promotion •Sales forcemanagement
•Communicationmanagement
•Stimulating patientcompliance
FIGURE 1Key Marketing Decision Areas in Life Sciences Firms
certification process). Life sciences is also one of the fewindustries in which manufacturers are legally prohibitedfrom communicating directly with their end customer (withthe exception of New Zealand and the United States).
The life sciences industry constitutes an important andgrowing part of the economy; for example, the U.S. life sci-ences industry represented $271 billion of global sales in2007 (Pharmaceutical Research and Manufacturers ofAmerica 2008). In the United States, prescription drugspending—the life sciences industry’s largest component—is expected to accelerate through 2017 (Centers forMedicare & Medicaid Services, Office of the Actuary2008).
Because of its vast importance and unique challenges,the marketing literature has recently turned to the lifesciences industry to study sales force effectiveness (Man-chanda and Chintagunta 2004; Manchanda and Honka2005; Manchanda, Rossi, and Chintagunta 2004; Mizik andJacobson 2004; Venkataraman and Stremersch 2007), ther-apy compliance (Bowman, Heilman, and Seetharaman2004; Wosinska 2005), communication effectiveness(Cleanthous 2004; Iizuka and Jin 2005; Macias and Lewis2003; Mukherji, Dutta, and Rajiv 2004; Wosinska 2006),and innovation (Chandy et al. 2006; Ding and Eliashberg2002; Prabhu, Chandy, and Ellis 2005; Sorescu, Chandy,and Prabhu 2003, 2007; Wuyts, Dutta, and Stremersch2004), among other areas.
The objectives of the current research are to evaluateprior research, suggest new directions for further research,and ignite life sciences marketing as an important area forscholarly research. We achieve these objectives by definingthe life sciences industry and discerning its boundaries,deriving the key marketing decision areas in this industry,formulating generalizations and propositions derived fromprior research and state-of-the-art practice, and steering fur-ther research in specific directions.
Defining the Life Sciences Industryand Its Boundaries
Underlying Dimensions of the Life SciencesIndustryA first constitutive characteristic of the life sciences indus-try is that this industry creates scientific knowledge regard-
1Nektar Therapeutics offers noninvasive deep-long delivery sys-tems. ArthroCare offers minimally invasive surgical proceduresinvolving tissue removal and treatment.
ing why a certain therapy affects the human body in a cer-tain way. Science represents “know-why” (Kogut and Zan-der 1992), in contrast to technology, which represents“know-how” (Quinn, Baruch, and Zien 1997). The averagenumber of scientific studies a firm cites when applying for apatent for its inventions (science linkage), rather than otherprior patents (know-how development), can be used as ameasure of the extent to which the firm is science based(Narin 2001).
A second constitutive characteristic of the life sciencesindustry is that the preventive or curative therapies it createsare scientifically reviewed regarding their effect on people’squality of life, after which they are promoted to patients andproviders to convince them of the acclaimed effects.Improvement in quality of life is expressed as an increase in“quality-adjusted life years” (often referred to as QALYs)and can lie in enhanced effectiveness, reduced side effects,and improved convenience (Garber and Phelps 1997). It isbased on both quantity and quality of life years generatedby the medical interventions.
The Components of the Life Sciences IndustryWe discern three components within the life sciences indus-try: pharmaceutical, biotechnological, and therapeuticmedical devices. These three industries are science basedbecause their patents typically refer to more scientific stud-ies than any other industry. For example, Narin (2001)shows that pharmaceutical and biotechnology firms, respec-tively, cited 7.3 and 14.4 scientific references per patent,which were the two highest science linkages of all technol-ogy areas. Though not separately identified in Narin’sstudy, therapeutic medical devices are also science based.First, the average science linkage of all medical devices andequipment companies, which includes therapeutic medicaldevices, is more than twice the average of the high-techindustry, such as aerospace or information and communica-tion technologies (Narin 2001). Second, therapeutic medi-cal devices companies, such as Nektar Therapeutics orArthroCare, belong to the most science-based companies inthe economy.1
6 / Journal of Marketing, July 2009
These three industries also market products that aim toimprove the quality of life. They market inorganic com-pounds (pharmaceutical), organic compounds (biotechnol-ogy), or therapeutic devices that affect the (diseased) humanbody. Take breast cancer as an example. Pharmaceuticalfirms aim to improve breast cancer patients’ conditionthrough chemotherapy, and biotechnology firms may offertargeted therapies in well-identified patient types (e.g., Her-ceptin by Genentech). Device-based therapies are also oftenused with the same objective of increasing quality-adjustedlife years (e.g., through radiotherapy).
Discerning the Boundaries of the Life SciencesIndustryOur definition of the life sciences industry enables us to dis-cern life sciences boundary industries (see Figure 2)—namely, cosmeceuticals, medical devices and equipment,and nutraceuticals. Each of these industries contains a smallsegment that belongs to the life sciences industry because itproduces therapies that are science based and improve qual-ity of life.
Typical cosmeceuticals are antiwrinkle agents or balmsto treat eczema or burning wounds. They prevent, treat, or
cure diseases, mostly of the skin. Therefore, they are dis-tinct from mere cosmetics, which aim to alter appearance ofthe skin, eyes, hair, nails, and so forth. Some cosmeceuti-cals (i.e., cosmetics-based therapies) are science based (e.g.,acne care products with therapeutic antiseptics).
Medical devices and equipment vary from wheelchairsto imaging devices (e.g., magnetic resonance imaging) tostents. Equipment such as wheelchairs improve the patient’squality of life (e.g., through mobility), but they are not sci-ence based. In contrast, medical imaging devices do nottherapeutically improve humans’ quality of life but repre-sent considerable know-why (science). Some devices (i.e.,device-based therapies), such as stents, implants, and pace-makers, enhance the quality of life and are science based;thus, they belong to the life sciences industry.
Nutraceuticals refer to products such as nutritional sup-plements, vitamin- or calcium-enriched foods, and polyun-saturated fatty acids. Nutraceuticals may improve quality oflife beyond merely feeding the body (foods). However, onlya subset of these products (i.e., food-based therapies) is sci-ence based and, thus, part of the life sciences industry. Anexample is sterol-derived, cholesterol-lowering BENECOL.
Therapies exist that include both a device and a cosme-ceutical or nutraceutical component. Examples includebreast implants (cosmeceuticals and devices) and nutri-genomics, that is, personalized diet recommendations basedon diagnostics of bodily fluids (nutraceuticals and devices).Figure 3 positions the life sciences industry in the healthcare market (adapted from Burns 2005). Payment flowsfrom left to right, from payers to providers, over financialintermediaries. Products flow from right to left, from pro-ducers to providers, over product intermediaries. The lifesciences industry is the producer side of the health caremarket.
Key Marketing Decision Areas inthe Life Sciences Industry
Next, we derive the key decision areas for marketers in thelife sciences industry. We first discuss our methodology,after which we identify and qualify the key marketing deci-sion areas on managerial relevance and scholarly potential.
FIGURE 2The Life Sciences Industry and Its Boundaries
Device-basedtherapies
Life Sciences
Medical devicesand equipment
Nutrac
eutic
als
Boundary Industries
Food-
base
d
thera
pies
Cosmetics-
basedtherapies
Cosmeceuticals
FIGURE 3The Life Sciences Industry in the Health Care Market
Government
Patients
Employers
Insurers
Health maintenance organizations
The life sciences Industry and its
boundary industries
Pharmacies
Wholesalers
Group purchasing organizations
Hospitals
Physicians
Integrated delivery networks
Financial Intermediaries Payers Providers
Product Intermediaries Producers
Source: Adapted from Burns (2005).
Marketing of the Life Sciences / 7
FIGURE 4Methodology
AcademicLiterature Review
Practitioner Literature Review
Marketing AcademicsOnline Survey
Low High
Low
High
Identifying MarketingDecision Areas and Domains
Qualifying FurtherResearch
Step 1
Step 2
Step 3b Step 3c
Step 5
Step 3a
Low High
Low
High
Step 4Performance-
enhancingdecision
areas
Ancillarydecision
areas
Criticaldecision
areas
Health-enhancingdecision
areas
Knowledge-enhancingresearch
Incrementalresearch
High-impact
research
Practice-enhancingresearch
Life Sciences MarketingPractitioners
Personal Interviews
Identified Life Sciences Marketing Decision Areas
Preidentified Life Sciences Marketing Decision Areas
Life Sciences Marketing Decision Areas Future
Research Need
Life Sciences Marketing Practitioner Telephone
Survey
Healthcare Payer and Provider Telephone
Survey
Life Sciences Marketing Decision Areas Importance Rating
2Our sample of academic literature included (1) marketing jour-nals, such as Journal of Marketing; (2) journals on the boundariesof the marketing discipline, such as Management Science; (3) spe-cialized journals in life sciences and health economics, such asJournal of Health Economics; (4) recent proceedings of confer-ences, such as the INFORMS Marketing Science Conference(2000–2008) and the Association for Consumer Research confer-ence (2000–2008); and (5) unpublished working papers. In thestudy of the industry literature, we included Journal of MedicalMarketing, Life Sciences, Medical Device Technology, MedicalMarketing & Media, Pharmaceutical Executive, and Pharma Mar-keting News, among others.
MethodologyFigure 4 graphically depicts our methodology. We firstidentified marketing decision areas in life sciences from aliterature study (Step 1).2 Appendix A provides an overviewof the major publications in life sciences marketing accord-ing to the three areas we defined—therapy creation, launch,and promotion. These publications include InternationalJournal of Research in Marketing, Journal of ConsumerResearch, Journal of Marketing, Journal of Marketing
Research, and Marketing Science, which have been used inprior research as a good representation of the major journalsin marketing (Stremersch and Verhoef 2005; Stremersch,Verniers, and Verhoef 2007).
Given its relatedness in the health care value chain,Appendix B provides an overview of the health psychologyliterature in the same major marketing journals. It discernsthree frameworks in this literature: health-related behavior,health risk perception, and health communication. Twoearly schools of thought underlie these frameworks: protec-tion motivation theory and the health belief model. Protec-tion motivation theory predicts protection intentions as afunction of severity, vulnerability, response efficacy, andself-efficacy and is used to test the effectiveness of healthcommunication (Maddux and Rogers 1983; Rogers 1975;see also Keller and Lehmann 2008). The health beliefmodel (Becker 1974; Rosenstock 1974) proposes thatincreasing risk perceptions should lead to precautionarybehavior (see Menon, Raghubir, and Agrawal 2008).
Though more distant to the life sciences marketingfield, we also reviewed the health economics literature. Theliterature provides good reviews on the cost of innovation
8 / Journal of Marketing, July 2009
(see DiMasi, Hansen, and Grabowski 2003), price competi-tion among pharmaceutical firms (see Bhattacharya andVogt 2003; Scherer 1993), the effect of generic entry onbranded drug prices (see Frank and Salkever 1997;Grabowski and Vernon 1992), health care policy (see Drum-mond, Jönsson, and Rutten 1997; Scherer 2004), and refer-ence pricing (see López-Casasnovas and Puig-Junoy 2000).
In Step 2, we conducted two-hour personal interviewswith nine marketing experts in life sciences companies,such as Amgen, GlaxoSmithKline, Novartis, Novo Nordisk,and Philips Medical Systems. To have sufficient confidencein our findings and to qualify the marketing decision areaswe identified in terms of importance, we conducted quanti-tative telephone surveys with marketing managers at lifesciences firms and with health care payers and providers,and we conducted an online survey of marketing academics.
We sampled marketing managers (Step 3a) using asnowballing technique, first contacting respondents weknew personally, then contacting executives the firstrespondents identified as useful respondents, and so on. Intotal, we contacted 110 executives, 96 of whom agreed toparticipate in the telephone interview (for a response rate of87%): 40 managers of pharmaceutical firms (e.g., AstellasPharma, AstraZeneca, Bristol-Myers Squibb, Glaxo-SmithKline, Johnson & Johnson, MSD, Novartis, NovoNordisk, Organon, Pfizer, Roche, Sanofi-Aventis, Schering-Plough, Wyeth), 28 managers of biotech firms (e.g., Amgen,Biogen Idec, Galapagos, Genzyme, Novo Nordisk,Organon), and 28 managers of medical devices companies(e.g., 3M Medical Specialties, AGFA HealthCare, B. Braun,Coloplast, Johnson & Johnson, Philips Medical Systems,Siemens Medical Solutions). We overweighted the pharma-ceutical industry, given its larger size compared with theothers. From these managers, we inventoried key decisionareas (open question) and the importance of each previouslyidentified (Steps 1 and 2) decision area for the firm on a 1–7 scale.
We sampled health care payers and providers (Step 3b)from contact lists provided by IMS Health. From a sampleof 545 payers and providers, 112 respondents participated(for a response rate of 21%), 81 of whom were physicians(health care providers) and 31 of whom were representa-tives of health care government and health managementorganizations (health care payers). From this sample, weassessed the impact of the previously identified (Steps 1–3a) marketing decision areas on patient welfare on a 1–7scale.
We sampled academics (Step 3c) using two criteria: (1)They had a position in marketing, and (2) they had knowl-edge relevant to the life sciences industry through their aca-demic research. From a sample of 78, the following 29 aca-demics eventually participated (for a response rate of 37%):N. Agrawal, M. Ahearne, R. Bezawada, L. Bolton, D. Bow-man, R. Chandy, A. Ching, M. Dekimpe, M. Ding, X.Dong, J. Eliashberg, P.A. Keller, L. Krishnamurthi, M.F.Luce, P. Manchanda, M.K. Mantrala, N. Mizik, C. Moor-man, H. Nair, J.C. Prabhu, V. Shankar, C. Sismeiro, A.Sorescu, E.R. Spangenberg, P. Stern, D. Vakratsas, C. Vanden Bulte, S. Venkataraman, and S. Wuyts. For each of thepreviously identified marketing decision areas (Steps 1–3a),
3The responses of payers were similar to the responses ofproviders. The correlation between the average ratings across bothgroups of respondents was .90, yielding a similar ranking onimportance of decision areas.
we asked the academics to assess (on a 1–7 scale) the extentto which (1) they are covered by current marketing researchin progress, (2) they deserve more scholarly attention in thefuture, and (3) they are perceived by academics as impor-tant for life sciences marketers in practice.
Step 4 yields the practical impact of life sciences mar-keting decision areas from both a firm profit perspectiveand a patient welfare perspective. Step 5 consists of map-ping the need for academic research, as perceived by acade-mics, onto decision area importance, as perceived by practi-tioners (combining the input of both marketing managersand health care providers and payers).
Identification of Key Marketing Decision AreasFigure 1 contains the marketing decision areas we retainedas key areas, grouped into three higher-level decisiondomains: therapy creation, therapy launch, and therapy pro-motion. In therapy creation, the key decision areas are ther-apy pipeline optimization, innovation alliance formation,and therapy positioning. The key decision areas in therapylaunch are global market entry timing and key opinionleader selection. The key decision areas in therapy promo-tion are sales force management, communication manage-ment, and stimulating patient compliance. Table 1 describeseach decision area. The second column presents the clarifi-cation we provided to respondents when we asked them torate the decision area’s importance. The third column con-tains the associations respondents made for each decisionarea during our interviews.
Qualifying Key Marketing Decision Areas in Termsof Research PotentialIn Step 4 (for more details, see Figure 5), we join relevancein terms of business performance (averaged over all life sci-ences firms we surveyed) and relevance in terms of patientwelfare (average of the averages over all surveyed payers onthe one hand and all surveyed providers on the other hand3).Average importance to business performance ranged from4.8 (innovation alliance formation) to 5.6 (sales force man-agement), while average importance ratings to patient wel-fare ranged from 3.6 (therapy positioning) to 5.2 (commu-nication management), all on a scale ranging from 1 to 7. In Figure 4, we qualify the different cells as follows: (1)“Critical decision areas” are of above-median importance to both business performance and patient welfare, (2)performance-enhancing decision areas are of above-medianimportance to business performance and of below-medianimportance to patient welfare, (3) health-enhancing deci-sion areas are of below-median importance to business per-formance and of above-median importance to patient wel-fare, and (4) ancillary decision areas are of below-medianimportance to both business performance and patientwelfare.
Communication management and key opinion leaderselection appear to be critical decision areas. Global market
Marketing of the Life Sciences / 9
Decision Area Clarification Provided to Respondents Associations That Respondents Made
Therapy CreationTherapy pipeline
optimizationsIncludes premarket decisions on portfolio or
pipeline optimization.“Our pipelines of the future will have to
contain more targeted therapy-diagnosticcombination projects.” (Johnson & Johnson)
Innovation allianceformation
Includes decisions regarding alliancesduring product development.
“How do we get synergy amongst alliancepartners?” (Philips Medical Systems)
Therapy positioning Includes premarket decisions oncompetitive positioning (including
segmentation, targeting) of the product.
“Instead of being product-minded, we shouldbecome more solution-minded.” (Philips
Medical Systems)
Therapy LaunchGlobal market entry timing Includes decisions regarding optimal market
entry timing, pioneer versus followeradvantages, international launch strategy,
and new product market potentialforecasting.
“At present, marketing and pricing is toocountry specific. How do we make a goodtrade-off between local and global market
entry?” (Johnson & Johnson)
Key opinion leaderselection
Includes the structuring of the company’skey opinion leader network for maximum
effectiveness.
“We assured fast product uptake in a sociallyretarded area by convincing the members ofa local fertility control council exerting high
impact on the local doctors.” (Organon)
Therapy PromotionSales force management Includes decisions on optimal sizing and
targeting of the sales force, decisions thatoptimize sales call quality, and the optimal
use of product samples, including salesresponse models.
“It is absolutely necessary for sales people tohave the level necessary to build
relationships with healthcare providers.”(B. Braun)
Communicationmanagement
Includes the design of optimalcommunication strategies, including the use
of medical publications, DTCA, andInternet-based communications that reach
patient and physician disease communities.
“How to reach patients with the presentregulatory restrictions?” (Roche)
Stimulating patientcompliance
Includes the design of optimal patientcompliance programs.
“There’s a gamut of new technologies, likesmart pill bottles, coming available now tosupport compliance. We should consider
them in our product delivery designs.”(Johnson & Johnson)
TABLE 1Description of Key Decision Areas in Our Survey
FIGURE 5Importance of Decision Areas to Firm
Performance and Patient Welfare
Impo
rtan
ce t
o P
atie
nt W
elfa
re
Importance to Life SciencesBusiness Performance
Below Median Above Median
AboveMedian
•Therapy pipelineoptimization
•Stimulating patientcompliance
•Communicationmanagement
•Key opinion leaderselection
BelowMedian
•Innovation allianceformation
•Therapypositioning
•Global marketentry timing
•Sales forcemanagement
entry timing and sales force management are performance-enhancing decision areas. The low relevance of sales forcemanagement to patient welfare may explain why manyhospitals and physicians have begun to deny access to phar-maceutical sales representatives. Therapy pipeline opti-mization and stimulating patient compliance are health-enhancing decision areas. Innovation alliance formation andtherapy positioning decisions are ancillary, probably to ther-apy pipeline optimization.
In Step 5 (for more details, see Figure 6), we confrontthe practical importance of decision areas (taken to be thehighest of importance in terms of business performance andpatient welfare) with the need for academic research, asperceived by academics. The average need for further acad-emic research ranges from 5.0 (sales force management) to5.8 (stimulating patient compliance) on a scale ranging
10 / Journal of Marketing, July 2009
FIGURE 6Research Agenda
Impo
rtan
ce t
o Li
fe S
cien
ces
Bus
ines
s P
erfo
rman
ce a
ndP
atie
nt W
elfa
reFuture Research Need
Below Median Above Median
AboveMedian
•Communicationmanagement
•Sales forcemanagement
•Therapy pipelineoptimization
•Global marketentry timing
•Key opinionleader selection
•Stimulatingpatientcompliance
BelowMedian
•Therapypositioning
•Innovationallianceformation
from 1 to 7. In Figure 4, we qualify the cells as follows: (1)High-impact research is research that promises to be animportant contribution to academic knowledge and of high,immediate, practical relevance to business performanceand/or patient welfare; (2) knowledge-enhancing research isresearch that promises to be an important contribution toacademic knowledge but is not necessarily of immediate,practical relevance; (3) practice-enhancing research isresearch of high, immediate, practical relevance to businessperformance and/or patient welfare but is not necessarily ofimmediate academic importance; and (4) incrementalresearch is research that is neither of high, immediate, prac-tical relevance nor necessarily an important contribution toacademic knowledge.
Although all four types of research are valuable in theirown right, the chance of gaining a breakthrough insight isthe highest in the “high-impact” (top-right) quadrant ofStep 5 in Figure 4 (for more details, see Figure 6). Suchdecision areas are therapy pipeline optimization, globalmarket entry timing, key opinion leader selection, andstimulating patient compliance. Further research on innova-tion alliance formation is qualified as knowledge-enhancingresearch. The academic knowledge generated can be ancil-lary to decision areas such as therapy pipeline optimization.Communication and sales force management are practice-enhancing areas. Research on therapy positioning is likelyto be incremental.
Academics assessed the need for further research ontherapy positioning as low because they considered thisdecision area of low practical relevance, while they assessedthe need for further research on sales force and communica-tion management as low because it is already largelyaddressed in prior and ongoing research, even though itsrelevance remains high.
Generalizations, Propositions, andDirections for Further Research
Drawing on prior research and practice, we formulate pre-liminary generalizations (G) to evaluate early streams ofresearch in this area, and we develop propositions (P) that
provide direction for further research. Preliminary generali-zations are already supported by the existing literature, butthey may benefit from additional testing through techniquessuch as meta-analyses. Propositions are exploratory and atleast partly supported by verbal logic, mathematical proof,or empirical evidence (Stremersch and Tellis 2002).
Therapy CreationTherapy pipeline optimization. In life sciences firms,
therapy pipelines contain all innovation projects along thefollowing temporal stages: During discovery, therapy candi-dates are screened for maximum activity on the biologicaltarget. Preclinical development and clinical developmententail further development, using in vitro or animal experi-ments and human experiments, respectively.
Prior research on therapy pipelines aimed to determinethe optimal number and sequencing of innovation projectsthat a firm’s resource base could support and that served itsgoal to maximize the number of commercially launchedinnovations (see Blau et al. 2004; Chandy et al. 2006; Dingand Eliashberg 2002; Loch and Kavadias 2002). Thisresearch found that there is an inverted U-shaped relation-ship between the number of innovation projects undertakenand the number of innovations commercially launched.However, scholars in this literature stream did not discernthe different temporal stages in the therapy pipeline.Although companies’ ability to convert innovation projectsin commercially launched products may suffer from takingon too many projects in development, this may not be thecase in discovery, in which more exploration leads to moreeffective knowledge on biological targets, resulting in morenew therapy opportunities. Thus:
P1a: There is a positive relationship between the number ofinnovation discovery projects initiated and the number ofpatented inventions of a firm.
P1b: There is an inverted U-shaped relationship between thenumber of innovation development projects initiated andthe number of commercially launched innovations of afirm.
The optimal number of innovation development projectsa firm should undertake may also be contingent on the typeof innovation project. Targeted (specific for certain patienttypes) therapy innovation projects require fewer resourcesin development and feature higher probabilities of ultimateregulatory approval (Vernon and Hughen 2005). Thus:
P2: Innovation development projects on targeted therapies leadto more commercially launched innovations than the samenumber of innovation development projects on nontar-geted therapies.
Scholars might also study other types of innovation pro-jects as contingency factors beyond targeted or nontargetedprojects, such as radical versus incremental projects. Study-ing the therapy pipeline in the context of patent expirymight also be fruitful. Firms may anticipate expiry in multi-ple ways, such as the development of combination drugs,more convenient administration and dosage methods, andreengineered variants with higher effectiveness or less seri-ous side effects. To develop and test such a contingencyframework, scholars could analyze databases, such as the
Marketing of the Life Sciences / 11
Pharmaprojects database, the R&D Focus Database thatIMS Health maintains, and the Food and Drug Administra-tion’s (FDA’s) Orange Book, all of which contain detailedpipeline information. As outcome variables, scholars couldgather information on the number of approved new patents(U.S. Patent and Trademark Office) and new therapies (theFDA’s Orange Book). Beyond direct innovation measures,they could also examine the impact of therapy pipelinedecisions on sales, profits, or stock market returns.
Innovation alliance formation. As we noted previously,practitioners consider decisions on innovation alliancesancillary decisions. At the same time, this decision area hasprovided an ideal and often-used testing ground for theorydevelopment on interfirm cooperation. The reason is thatthe life sciences industry provides possibly the richest docu-mentation on such alliances (e.g., Recap’s database oninterfirm agreements) and their outcomes (e.g., patents, newproducts, profits, sales, share price).
Similarity between parties in an alliance is probablymost often studied. Dissimilarity between partners yieldsgreater learning opportunity because there is less knowl-edge redundancy, while similarity between partners makesit easier to understand each other and share information.The tension between both arguments has led manyresearchers (Cloodt, Hagedoorn, and Van Kranenburg 2006;Prabhu, Chandy, and Ellis 2005; Wuyts et al. 2005) to find acurvilinear relationship between knowledge similaritybetween alliance partners and the innovative outcome thatthe alliance yields. This leads us to the following prelimi-nary generalization:
G1: There is an inverted U-shaped relationship betweenknowledge similarity between alliance partners and thenumber of new therapies the alliance yields.
Scholars have also studied the differential effect ofalliances on radical versus incremental innovation (Wuyts,Dutta, and Stremersch 2004). For radical innovation, it isinstrumental that alliance partners repeatedly cooperate tostimulate knowledge transfer through the development ofrelationship-specific heuristics and the sharing of mentalmodels, among other things (Madhaven and Grover 1998;Uzzi 1997). Genentech and Roche provide a successfulexample of such repeated collaboration. For incrementalinnovation, large portfolios may be beneficial because ofscale effects in development (Ahuja 2000; Wuyts, Dutta,and Stremersch 2004). We offer the following preliminarygeneralizations:
G2: As the level of repeated partnering in a firm’s innovationalliances portfolio increases, its radical innovation outputincreases.
G3: As the number of alliance partners in a firm’s innovationalliances portfolio increases, its incremental innovationoutput increases.
Further research on interfirm cooperation will likelycontinue to use the life sciences industry as a testing groundfor theory development, with continued use of databases(e.g., Pharmaprojects, Recap), newspapers and magazines,and surveys. Novel breakthroughs are likely to be in the
areas of social networks and the balance between internaland external innovation.
Therapy positioning. Therapy positioning refers toresearch-and-development (R&D) decisions on the envi-sioned therapy toward specific indications. The practition-ers we surveyed considered therapy positioning an ancillarydecision area, while academics did not foresee a strongneed for further research. Therefore, we do not derive theo-retical generalizations or propositions. Decision makersneed to balance three key dimensions: (1) the likelihoodthat the therapy will be approved for the respective indica-tion, (2) the price they will obtain from the therapy, and (3)the market size for the respective indication over time.
If positioned for a mild indication, a therapy may reacha large market, but at relatively low prices and with possibledenial of approval. Consider Elidel (pimecrolimus), a ther-apy for eczema by Novartis. Novartis introduced Elidel fora mild to moderate indication of eczema—that is, for first-line use. Competitor Fujisawa introduced a variant of thismolecule, Prograf (tacrolimus), which was targeted at mod-erate to severe indications of eczema—that is, for second-line use. Although both products showed scientific evi-dence, only tacrolimus was endorsed by the U.K.government, because the former could not show that it rep-resented a good value for the money (Gregson et al. 2005)for the moderate indication. It was subsequently endorsedafter resubmission, but then also for the severe indication. Ifpositioned for a severe indication, a therapy may have ahigher likelihood of being approved at a high price, but itmay pertain to a relatively small market. For example, Sym-bicort by AstraZeneca was first approved for severe asthma,after which AstraZeneca enlarged the market for Symbicortto chronic obstructive pulmonary disease (COPD).
Because there are many possible indications, all withdifferent levels of uncertainty for the respective therapy tobe approved and varying price expectations, furtherresearch should aim to specify decision support models thatsimulate market size using patient flow dynamics (first use,reuse, switching from competition) at various price expecta-tions and approval likelihoods.
Therapy LaunchGlobal market entry timing. Previous research has
shown that pioneers do not have long-lasting market advan-tages (Golder and Tellis 1993; Shankar, Carpenter, andKrishnamurthi 1999). In the life sciences industry, animportant moderator of the market return on a pioneeringtherapy may be whether it pertains to generic or brandedtherapies. In the case of branded therapies, pioneers are thefirst entrants in a therapeutic category (e.g., Mevacor [1987]for statins). In the case of generic therapies, pioneers are thefirst generic available for a specific therapy (e.g., the firstgeneric Simvastatin, the statin introduced by Merck asZocor).
There are many cases of late branded entrants that tookover pioneers through increased effectiveness, higher con-venience, or weaker side effects. Examples include Zocorand Lipitor in statins (increased effectiveness), Symbicort
12 / Journal of Marketing, July 2009
in asthma/COPD (higher convenience), and Xyzal in anti-histamines (weaker side effects).
Contrary to common wisdom in other industries andcontrary to branded variants in life sciences, generics mayyield strong pioneering advantages. The first generic variantfor a specific therapy (“the pioneer”) may attract and main-tain a disproportionately large market share. The reasons forthis are multifold. It takes substantial effort from physiciansand pharmacists to explain bioequivalence between differ-ent variants (Gupta, Yu, and Guha 2006). At the same time,only the pioneering generic therapy benefits from the largeprice differential with the alternative (the branded variant).Generics that subsequently enter do not show as large of aprice differential anymore, and when they do, the genericpioneer may readily match the lower price, with marketshares remaining stable (Hollis 2002). The first genericentrant also typically makes supranormal profits before theentry of a second generic because it provides the only(cheap) alternative for an expensive branded variant (Gupta,Yu, and Guha 2006). Thus:
P3: Pioneering yields market share advantages for generictherapies.
The life sciences industry lends itself well to the exami-nation of order-of-entry effects because entry is well docu-mented (e.g., with the FDA Drugs@FDA for the UnitedStates). These entry dates can be complemented with IMSHealth’s dollar sales estimates. Moderators that could beconsidered in such research effort are clinical profile of thetreatment (e.g., from National Institute for Health and Clin-ical Excellence or published meta-analyses in scientificjournals) and marketing support (commonly available fromfirms such as IMS Health, Kluwer, or Verispan).
Firms typically do not launch a new treatment simulta-neously across the globe. Rather, they use specific launchsequences, often driven by a country’s regulatory system,economic wealth, and size (Danzon, Wang, and Wang 2005;Kyle 2007; Verniers, Stremersch, and Croux 2008). Differ-ential launch timing across countries has been shown not toaffect unit sales (Stremersch and Lemmens 2009), though ithas been shown to affect launch price (Verniers, Strem-ersch, and Croux 2008). In the life sciences industry, launchprice is rarely a market price; rather, it is often an agreed-onprice between the supplier and the government or insurancefirm, which acts as a (co)payer. In such negotiations, entrytiming may be used by both the payer and the firm as aninstrument to affect the agreed-on price.
An important contingency factor that has not receivedany attention is the role of cross-country influence in launchsequencing. Often, this cross-country influence is institu-tionalized because payers will use the price of a therapy in adefined set of other countries (the “referent” countries), ifavailable, as a reference price for the negotiations in theirown country (the “referencing” country). Such regulationincentivizes companies to avoid spillover effects (Hunter2005). Thus:
P4: Firms that launch a new therapy in a referencing countryearly relative to the set of referent countries obtain ahigher price than firms that launch a new therapy in a
referencing country late relative to the set of referentcountries.
To test this proposition, regulatory data can be gatheredfrom Urch Publishing and the Organisation for EconomicCo-operation and Development, both of which track inter-national regulatory health systems (including identificationof the set of referent countries for each referencing coun-try), and integrated with IMS Health data on internationalprices and introduction dates. It is also possible to includefirm effects (firms may have differential policies, dependingon their home market or size) or therapy effects (payersacross countries may have differential price and marketaccess policies for different therapy classes). In addition,diffusion studies can deliver valuable and complementaryinsights into launch decisions. Examples of such valuableinquiries that may inform launch decisions are improvedmodels of physician learning and international diffusionstudies.
Key opinion leader selection. Life sciences firms oftenstimulate reviews of their therapy by select key opinionleaders because such leaders may serve as product champi-ons to their peers. The effect of such opinion leaders onother physicians’ prescriptions can be large when consider-able uncertainty exists (e.g., a change in the regulation orthe introduction of a new therapy) or when physiciansexperience normative pressures (e.g., there is strong formu-lary adherence) (Coleman, Katz, and Menzel 1966; Iyengar,Valente, and Van den Bulte 2008). For example, Nair, Man-chanda, and Bhatia (2006) show that the effect of opinionleader prescriptions is 100 times larger than the detailingeffect on regular physicians after the market underwent achange in National Institutes of Health guidelines.
However, we cannot take the positive role of opinionleaders for granted (e.g., Van den Bulte and Lilien 2001),and further research should inventory the contingencies thataffect the role of opinion leaders. In such research, it isworthwhile to consider two types of key opinion leaderswith potentially differential effectiveness: clinical and mar-ket leaders. Clinical leaders are experts within the respec-tive disease and therapy class with a strong reputation, asevidenced by their publication records in top-ranked medi-cal journals. They are typically involved in premarket prod-uct testing and have cooperated with the firm to reduce clin-ical uncertainty of the therapy. In contrast, market leadersare tightly connected to the local patient and physiciancommunities. They are typically general practitioners withlarge practices who gain recognition by the satisfaction andloyalty of their patients. They deliver key experiential mes-sages on the therapy to their peers.
For example, as a contingency factor, consider whetheruncertainty manifests in terms of effectiveness or sideeffects of a life sciences therapy. The impact of uncertaintyon effectiveness can be reduced through quantitative assess-ments without much detail on specific physician practices(i.e., large scale, study based). Conversely, the impact ofside effects information is more qualitative and dependenton the specific composition of a practice (i.e., case based).Because clinical leaders support quantitative assessments ofeffectiveness and market leaders share case detail on side
Marketing of the Life Sciences / 13
effects from practices similar to other physicians, we pro-pose the following:
P5a: The greater the uncertainty on therapy effectiveness, thehigher is the impact of clinical leaders, compared withmarket leaders, on other physicians’ prescriptionbehavior.
P5b: The greater the uncertainty on therapy side effects, thehigher is the impact of market leaders, compared withclinical leaders, on other physicians’ prescriptionbehavior.
Another contingency factor to consider is the physi-cian’s institutional setting. Hospitals have formal ethicalguidelines (Gallego, Taylor, and Brien 2007) to which anindividual practitioner must adhere, which increases thereturn on legitimacy compared with general practitioners.Clinical leaders enhance legitimacy to a greater degree thanmarket leaders, which fits with their high impact on formu-lary decisions. At the same time, market leaders achievetheir influence through similarity of practice. In general, thepractice of a market leader is more similar to a general prac-titioner practice than to a hospital-based practice. Thus:
P6a: Clinical leaders have a greater impact on hospital-basedphysicians’ prescription behavior than market leaders.
P6b: Market leaders have a greater impact on general practi-tioners’ prescription behavior than clinical leaders.
Researching these propositions can include surveying allphysicians of a certain area to inventory their opinion lead-ers, including Likert-type scales on each of the identifiedleaders regarding the extent to which they are clinical and/or market leaders.
Therapy PromotionSales force management. A first decision area in therapy
promotion is sales force management. Visits by the salesforce of life sciences firms to physicians are referred to as“detailing.” Much academic research has emerged on theeffectiveness (return on investment) of detailing (Azoulay2002; Berndt et al. 1995; Leeflang, Wieringa, and Wittink2004; Manchanda and Chintagunta 2004; Manchanda,Dong, and Chintagunta 2004; Manchanda and Honka 2005;Manchanda, Rossi, and Chintagunta 2004; Mantrala, Sinha,and Zoltners 1994; Mizik and Jacobson 2004; Narayanan,Desiraju, and Chintagunta 2004; Narayanan, Manchanda,and Chintagunta 2005; Parsons and Vanden Abeele 1981;Venkataraman and Stremersch 2007). We derive the follow-ing generalization from this literature:
G4: The mean effect of detailing on brand prescriptions is (a)positive but (b) small.
“Mean” in G4 refers to the mean across brands andphysicians. Prior literature has shown high physician- anddrug-level heterogeneity, including some brands and physi-cians showing a negative return on detailing (Leeflang,Wieringa, and Wittink 2004), and has investigated specificcontingency factors, such as drug characteristics (e.g., sideeffects, effectiveness [Venkataraman and Stremersch 2007],and physician traits [e.g., Gönül et al. 2001]).
There is room for further study. A first opportunity is toincrease the reliability of this preliminary generalization
through meta-analysis. Kremer and colleagues (2008) offera first attempt at such generalization, but they provide onlya limited number of significant moderators and omit drugs’clinical profile. A second opportunity lies in the develop-ment of models that allow for policy experiments. Althoughwe have reliable estimates of the mean effect of detailing,all models are estimated on data that show relatively littlepolicy variance, which inhibits any extrapolation to policyshifts in detailing, either by the manufacturer (many firmsare now considering drastically reducing their detailingefforts) or by the regulator (several European countries areconsidering curtailing detailing). The third opportunity liesin developing physician targeting models based on volume,physician responsiveness to detailing, and competitivedetailing patterns (for working papers in this tradition, seeDong, Manchanda, and Chintagunta 2008; Kappe, Strem-ersch, and Venkataraman 2008).
By far, the most room for novel research seems to be inthe content of detailing visits. Past and, for most companies,present detailing calls present only favorable informationusing positively biased information sets—that is, only stud-ies favorable to the brand are presented, or side effects areomitted. This sales model seems increasingly dysfunctional,with hospitals and physicians reacting adversely to detail-ing, even rejecting it altogether, which is symptomatic forthe conflicting logics between life sciences firms and therest of the health care value chain (Singh, Jayanti, and Gan-non 2008).
We propose that life sciences firms can gain substantialreturns from communicating unfavorable information intheir detailing calls, for two main reasons (Leffler 1981).First, in view of their ethical, gatekeeping function topatients, physicians prefer more complete information, evenif unfavorable, over ambiguity. Second, communicatingunfavorable information may enhance the legitimacy of thesales representative and the firm (Singh, Jayanti, and Gan-non 2008). In turn, this enhanced legitimacy may deliversustained physician access and increased trust in the firm’smessages. Both will strengthen long-term return on invest-ment from detailing. Thus:
P7a: Communication of complete (including both favorableand unfavorable) therapy information in sales calls mayaffect more positively the firm’s long-term return oninvestment from detailing than just communicating favor-able therapy information.
P7b: The effect postulated in P7a is larger in the case of thera-pies for life-threatening illnesses than in the case of non-life-threatening illnesses.
P7c: The relationship postulated in P7a is larger in hospitalenvironments than in outpatient environments.
In P7b and P7c, we conjecture that the effect of disclo-sure of complete information may be contingent on whetherthe disease is life threatening and on the physician’s institu-tional setting. Agents confronted with a decision of highimportance attach a greater value to information (Celsi andOlson 1988). Therefore, physicians’ preference for morecomplete information, even if unfavorable, over ambiguitywill be higher in the case of life-threatening diseases than inthe case of non-life-threatening diseases. For example, there
14 / Journal of Marketing, July 2009
is more value in reducing ambiguity about the side effectsof chemotherapy, even if it concerns an increased probabil-ity of pneumonia versus an increased probability of insom-nia caused by antihistamines. As we argued previously,practitioners in hospitals may have a higher return on legiti-macy than general practitioners in the outpatient environ-ment. Revealing unfavorable information together withfavorable information enhances a sales representative’slegitimacy.
There are several possible tests of P7a–P7c. IMSHealth’s U.S. panel data include data on which attributes ofa drug were discussed in a sales call. Adding information onhow drugs in a category compare on each of these attributesmay reveal whether favorable rather than unfavorable attrib-utes were discussed. Several individual firms have recordson which studies were covered in sales calls, which canreveal whether unfavorable studies were covered. Thereturn on investment from long-term detailing can beregressed on both types of data to test the propositions.Longitudinal experiments can also be conducted to test thepropositions, in which physicians or medical school stu-dents are detailed within a simulation.
Communication management. Although communicationefforts of life sciences firms may target both consumers andphysicians, the budgets dedicated to the former group aremore than ten times larger than the budgets dedicated to thelatter (Kremer et al. 2008), and from the interviews we heldwith practitioners, direct-to-consumer advertising (DTCA)is also the most challenging. The academic literature onDTCA (Berndt et al. 1995; Bowman, Heilman, andSeetharaman 2004; Iizuka and Jin 2005; Narayanan, Desir-aju, and Chintagunta 2004; Wosinka 2005) mostly exam-ines overall effectiveness of DTCA and yields the followingpreliminary generalization:
G5: DTCA has a positive effect on (a) the number of patientsseeing a physician for the respective disease for which atherapy is advertised and (b) total category-level demandin the category of the therapy that is advertised.
Further research on other potential outcomes of DTCA,such as its effect on brand choice, would be fruitful becauseit is fraught with debate. Iizuka and Jin (2005) and Wosin-ska (2005) find that DTCA does not affect drug brandchoice, while Berndt and colleagues (1995) and Narayanan,Desiraju, and Chintagunta (2004) find a positive effect ofDTCA on drug brand choice. Such research could involvemeta-analysis or the analysis of contingency frameworks.
An example of a contingency factor is the degree towhich DTCA messages include favorable and unfavorableinformation. Although unfavorable information (e.g., infor-mation on serious side effects of therapy) may arouse con-sumers (Moorman 1990), it may also yield negative emo-tions that hinder information processing (Agrawal, Menon,and Aaker 2007; Keller 1999). Thus:
P8: The effect of DTCA on brand-level demand is higher themore the advertisement depicts favorable, rather than unfa-vorable, therapy information.
At the same time, no study develops a process view onthe effects of DTCA on the demand for a specific therapy.
The process involves DTCA triggering a patient’s requestfor a therapy at the physician’s office, which the physiciancan accommodate or not. The role of patient requests andthe factors that affect the degree to which the physicianaccommodates them are not addressed in the academic lit-erature at this point (for an exception, see Venkataramanand Stremersch 2007). Developing such a process view mayyield relevant insights for managers (e.g., on audience tar-geting). As an example, consider audience gender. Priorresearch has shown that women are more concerned abouttheir health (Verbrugge 1985) and interact more assertivelyin health care settings (Kaplan et al. 1995) than men andthat physicians are more empathic to female than malepatients (Hooper et al. 1982). Consequently, DTCA maymore easily trigger requests among women, and femalerequests may be more easily accommodated by physiciansthan male requests. Thus:
P9: The effect of DTCA on brand-level demand is higheramong female viewers than among male viewers.
Many other boundary conditions can be formulated onaspects such as the type of disease and patient–physicianrelationships, all of which may inform ad content and targetaudience decisions of firms. Data availability on DTCA ishigh. Secondary data sources include ACNielsen and TNSMedia. Both data types can be connected with aggregate-level sales data (e.g., from IMS Health) or panel-level data(e.g., from IMS Health or Verispan). In addition, experi-mental studies may have high potential because they mayreveal underlying psychological processes.
Stimulating patient compliance. As our survey resultsshow, life sciences firms undervalue the importance ofstimulating patient compliance, from both a patient welfareand a profit perspective. Our interviews with managersrevealed that they consider their impact on patient compli-ance minimal, though they believe that it is mostly affectedby the provider in his or her interaction with the patient. Incontrast, our survey among providers and payers shows thatthey believe that life sciences firms’ efforts to stimulatepatient compliance may have important effects on patientwelfare.
Despite its high relevance, academic research has notstudied the role of the life sciences firm in patient compli-ance in depth. Prior research has found that provider exper-tise (Dellande, Gilly, and Graham 2004), the attitudinalhomophily between patient and provider (Dellande, Gilly,and Graham 2004), the frequency of contact betweenpatient and provider (Bowman, Heilman, and Seetharaman2004), reminder messages (Becker and Rosenstock 1984;Rosenstock 1985), and the burden of therapy (Kahn et al.1997; Kahn and Luce 2003, 2006) all affect patient compli-ance. The only research that exists on how life sciencesfirms may affect patient compliance examines warninglabels. For example, Ferguson, Discenza, and Miller (1987)find that warning labels that include information on the con-sequences of poor compliance are effective.
Today, life sciences firms sporadically institute newtypes of compliance programs, the effectiveness of whichremains void of academic scrutiny. We categorize such
Marketing of the Life Sciences / 15
compliance programs in technology-enabled and customerrelationship management– (CRM-) enabled programs.
Such CRM-enabled programs typically used in practiceare direct mail or call campaigns. Pfizer has developed a“Staying on Track” CRM program for its statin drug Lipitor(Arnold 2004). Such programs monitor patients’ diseaseand refill status, motivate patients to stay on therapy regi-men, and provide patients with therapy risk–related infor-mation tailored to the stage of therapy with their specificsymptoms and motivations (Hopfield, Linden, and Tevelow2006).
Technology-enabled programs include a technologicaldevice to remind patients to take their pills. Bang & OlufsenMedicon’s blister card–based “The Helping Hand” gives avisual indication of therapy compliance through red orgreen LEDs (light-emitting diodes) as soon as a blister isinserted into the device. Another example is “SIMPill,” asmart pill bottle that reminds patients through SMS (shortmessage service) that they have forgotten to take theirmedicine.
Both types of programs connect to different behavioralrationales for poor compliance: a patient’s belief in self-efficacy and mindfulness. A patient’s belief in self-efficacyrefers to the belief of being capable of carrying through theprescribed therapy, and mindfulness refers to awareness ofactions to be taken (Keller 2006). Customer relationshipmanagement–enabled programs promote a patient’s beliefin self-efficacy, and technology-enabled programs promotemindfulness. The potential of CRM programs to promotemindfulness is limited because the reminder frequencywithin a CRM program is unable to match therapy fre-quency (one or multiple therapy occurrences a day). Con-versely, technology programs cannot offer the patient inter-personal coaching (e.g., Bandura 1982) to stay on therapy.
Given their differential behavioral rationales, the effec-tiveness of both programs is likely to depend on factorssuch as disease complexity and symptom salience. First, themore complex a disease, the higher is the likelihood thatpoor compliance is driven by disbelief in self-efficacy. Assuch, CRM-enabled programs can effectively reduce suchuncertainty, but technology-enabled programs cannot. Sec-ond, the less salient the symptoms of a disease (e.g., the fluis a disease with salient symptoms and high cholesterol is adisease with low salience), the more compliance will be dri-ven by mindfulness. When salience is low, technology-enabled programs will be more effective in stimulatingcompliance than CRM-enabled programs.
P10a: As disease complexity increases, CRM-enabled compli-ance programs increase in effectiveness to stimulatepatient compliance, compared with technology-enabledcompliance programs.
P10b: As symptom salience decreases, technology-enabledcompliance programs increase in effectiveness to stimu-late patient compliance, compared with CRM-enabledcompliance programs.
Further research might consider a broader array of con-tingency factors than those developed in these propositions.Such research promises to be impactful for both academiaand practice, but at the same time, it is challenging to exe-
cute. Relatively few firms have instituted a compliance pro-gram, patient-level data are difficult to obtain, and patientsself-select into a program (which may cause sample selec-tion issues). One method may be to conduct a conjointexperiment using physicians as informants on patientbehavior. In such a conjoint experiment, program designfactors could be manipulated, and their effect on patientcompliance (as informed by the physician) could be esti-mated. Test–retest reliability and comparison with actualcases could further support the validity of such an approach.A more demanding alternative is cooperation with a life sci-ences firm that is open to a field experiment, including alongitudinal survey to the compliance program participants.More generally, the field of compliance would benefit fromextensive survey research across patient–physician relation-ships because compliance is intrinsically embedded in thisrelationship.
ConclusionSome industries require industry-specific knowledge devel-opment because they have unique characteristics that yieldspecific challenges for marketers. In this research, we aimto advocate such knowledge development for life sciencesmarketing. This article has implications for both life sci-ences marketing practice and academia.
Life Sciences Marketing PracticeDefining life sciences—to our surprise, no useful definitionexisted in the literature—proved to be challenging but, atthe same time, eye-opening. Discerning clear boundaries to the domain enabled us to demarcate boundary areas, such as cosmetics-, device-, and food-based therapies, whileintegrating pharmaceuticals, biotechnology, and medicaldevices. With an increasing patient-centered view on healthand personalization in medicine (see Camacho, Landsman,and Stremersch 2009), life sciences companies that developan integrated view on patients’ health—rather than consid-ering themselves a pharmaceutical, biotech, or medicaldevices company—will be best equipped for the future.Such integration is challenging. For example, with its his-torical structure along product divisions, Philips is chal-lenged to develop an integrated view on opportunities inpersonalized medicine because such opportunities oftenstretch across the firm’s personal care, medical devices, andconsumer electronics divisions. Another related challengefor life sciences firms is to enhance their typical curativeoffering to include prevention, patient monitoring, andpatient wellness. For example, firms with a diabetes fran-chise have moved historically from providing therapies(e.g., glucose) to providing monitoring devices (e.g., bloodmonitoring personal digital assistants) and, more recently,have faced the challenge to move into comprehensive care,which extends toward patient wellness (e.g., prevention andawareness on probable consequences of diabetes, such asblindness and wound care).
We also found substantial divergence in the evaluationof the importance of certain decision areas between life sci-ences marketers and health care payers and providers or,
16 / Journal of Marketing, July 2009
alternatively worded, between profits and patient welfare.While marketing managers emphasize the profit implica-tions of sales force management, health care payers andproviders emphasize patient welfare implications of life sci-ences firms’ actions to stimulate patient compliance. Suchdivergence gives rise to potential conflict in the health carevalue chain. As Singh, Jayanti, and Gannon (2008) argue,there is a strong need for the life sciences industry to escapesuch conflicting logic in the short run and increasinglyadopt a partnership model, which could lead to enhancedlegitimacy in the long run for life sciences firms.
Although further testing is needed, the generalizationsand propositions we derive may provoke some firms to altertheir marketing approach. For example, our propositions onopinion leaders encourage a dual-layer strategy of firms,such that at launch, they may rely on clinical leaders(mostly through research cooperation), and as experiencewith the therapy’s side effects grows, market leaders may be actively involved (e.g., through specialized detailing).Although some firms already have such a dual-layer strat-egy, this is not (yet) common practice among life sciencesfirms. Another example is the differentiation betweenCRM-enabled and technology-enabled compliance pro-grams. As the quotation from a Johnson & Johnson mar-keter in Table 1 shows, most life sciences firms are justbeginning to consider compliance programs. Our proposi-tions on compliance should encourage them to analyze theunderlying characteristics of the disease and the patients tosteer them to a suitable type of program. The review ofprior research and the generalizations we derive from it mayalso inform practice. The positive expectations of manyfirms regarding the effect of DTCA on brand sales (note thehigh spending on DTCA among life sciences firms) areunrealistic in light of prior research findings.
Life Sciences Marketing AcademiaThis article shows that a bright future for this nascent fieldwithin marketing is imminent (Stremersch 2008). Amongthe many reasons are that (1) this context presents uniqueand often challenging problems, (2) for which high-qualitydata are available and (3) that have an impact that tran-scends the problems typically investigated by marketingscholars. On the supply side, universities are likely to investconsiderable research funds in life sciences marketing as aresearch program that transcends various schools (business,medicine, economics), creates vast societal influence(regarding public policy, firms, the press, and the public atlarge), and does not have a pure for-profit nature (comparedwith other business school research).
We have demarcated the boundaries of this new domain;categorized the main decisions of life sciences marketers;and provided generalizations, propositions, and researchdirections to stimulate and steer research in this nascentfield. As with the advent of any new field, there are as manycynics who claim that nothing is fundamentally differentabout life sciences marketing and that conventional insightscan easily be extended to such markets without adaptationas there are enthusiasts who embrace these markets as beingas different as the moon is from the earth. The former groupoften finds a dominant argument in the data-driven nature ofthe original contributions to life sciences marketing. How-ever, in itself, this is not a reason an industry cannot beguided by different principles, thus leading to unique chal-lenges. The same applies to the argument that some chal-lenges are also present in other industries, in a slightly mod-ified form. In the dialectic tradition, we try to build the casefor the enthusiasts. Early interest at conferences, in jour-nals, and in MBA program offices seems to favor the enthu-siasts. The least we have hopefully achieved with this arti-cle is to define the playing field on which cynics andenthusiasts will interact, both in research and in teaching.
Marketing of the Life Sciences / 17
APPENDIX AOverview of Life Sciences Marketing Literature
AuthorsDecision
Areas Main FindingsConceptualFramework
MethodUsed Empirical Base
Therapy CreationSorescu,
Chandy, andPrabhu (2007)
IAF Pharmaceutical firms with large product capital assets are betterat selecting targets with innovation potential and deploying this
innovation potential. The performance consequences of thissuperiority in the selection and deployment of target firms
manifests itself in long-term financial rewards to the acquiringfirm.
Resource-based view of
the firm
Ordinary leastsquares (OLS)
regression model
238 acquisitions in 7 countries(1992–2002)
Chandy et al.(2006)
TPO Firms that (1) focus on a moderate number of ideas in areas ofimportance and in which they have expertise and (2) deliberate
for a moderate length of time on promising ideas have the highestconversion ability.
Problemsolving
Discrete choicemodel
322 drug ideas by 38 firms(1980–1985)
Prabhu, Chandy,and Ellis(2005)
IAF Innovation outcomes of acquisitions are driven by thepreacquisition knowledge of the acquirer and its similarity with the
target’s knowledge.
Knowledge-based view of
the firm
Distributed-lagmodel
35 pharmaceutical firms thatacquired 157 targets
(1988–1997)
Moorman, Du,and Mela(2005)
TP Firms can make strategic use of regulation by thinking aboutcosts and benefits of regulation relative to competition. The
introduction of the Nutrition Label and Education Act (NLEA)(Public Law 101-535) led to (1) an increase in small-share firmexits and (2) a greater increase in distribution for large-sharefirms. No concurrent increase in price by large-share firms
following the NLEA was observed.
Economics ofinformation
Random effectsprobit on
longitudinal quasi-experimental data
Universal Product Codes atthe firm and brand levels for109 categories from 2186
firms (Supermarket Reviewdata) and for 265 categoriesfrom 29,374 firms (Infoscan)per year (1991, 1993, and
1995)
Wuyts, Dutta,andStremersch(2004)
IAF Alliance portfolio technological diversity has a positive affect onincremental and radical innovation output but has a negative
direct effect on profitability. Repeated partnering has a positiveeffect on radical innovation and a curvilinear effect on profitability.
Alliance portfolio size has a positive effect on incrementalinnovation output and firm profitability.
Knowledge-based view of
the firm
Negative binomialand OLS
regression model
991 R&D agreements(1985–1998)
Sorescu,Chandy, andPrabhu (2003)
TPO Firms that provide higher per-product levels of marketing andtechnology support obtain much greater financial rewards from
their radical innovations than other firms. Firms that have greaterdepth and breadth in their product portfolio also gain more from
their radical innovations.
Risk- andresource-
based view ofthe firm
Random effectsPoisson model
255 breakthroughs introducedby 66 publicly traded firms
(1991–2000)
18/ Journal of M
arketing,July 2009
AuthorsDecision
Areas Main FindingsConceptualFramework
MethodUsed Empirical Base
Moorman andSlotegraaf(1999)
TP Product marketing and technology capabilities coinfluence thedegree to which firms improve the quality of their brands and the
speed of these improvements. Capabilities’ most valuablecharacteristic is to serve as flexible strategic options consistent
with a changing environment.
Resource-based view ofthe firm and
economics ofinformation
Regression onlongitudinal quasi-experimental data
124 brands across 22categories (1991–1993,
1994–1996)
Moorman (1998) TP Marketers respond to the introduction of the NLEA by changingthe quality of their brands and extensions, thus occupying distinct
strategic positions. It also shifts healthy brands away fromcompeting on price. Conversely, nonhealthy brands rely more on
price promotion post-NLEA.
Economics ofinformation
Regression onlongitudinal quasi-experimental data
269 consumers pre-NLEA, 212post-NLEA, 124 products
(1987–1996)
Therapy LaunchAboulnasr et al.
(2008)GMET The likelihood of competitive product response to radical
innovation is substantially higher when the introducing firm islarge or when it derives a larger part of its revenues from the
introduction market. The response is greatest when the radicalinnovation is introduced in a small market by a large firm.
New productgrowth
Hazard model 52 radical product innovationsintroduced by 32 different
companies in 27 therapeuticcategories (1997–2001)
Rao, Chandy,and Prabhu(2008)
GMET New biotech ventures that acquire legitimacy externally byforming alliances with established firms gain more from their new
products than new ventures that do not form such alliances.Among new ventures that do not form alliances, those thatacquire legitimacy internally by creating a history of product
launches or by hiring reputed executives or scientists gain morefrom their new products than those that do not. Pursuit of externallegitimacy by firms that already have internal legitimacy leads to
lower rewards to innovation.
New productgrowth
Maximum likelihoodestimation and
OLS regressions
93 FDA-approved biotechproduct introductions
(1982–2002)
Akçura, Gönül,and Petrova(2004)
GMET Price promotions may be deficient as a tool to increase marketshare in over-the-counter leg-and-back pain relievers.
Choicebehavior with
learning
Bayesian learningmodel with Kalman
filter
3519 purchase observation inpanel of 69 consumers of
over-the-counter leg-and-backpain relievers (1993–1995)
Desiraju, Nair,andChintagunta(2004)
GMET Developing countries have lower diffusion speeds than andmaximum penetration levels relative to developed countries.Laggard developed countries have higher speeds. Laggard
developing countries do not have higher diffusion speeds. Per-capita expenditures on health care have a positive effect ondiffusion speed (particularly for developed countries). Higher
prices tend to decrease diffusion speed.
New productgrowth
HierarchicalBayesian diffusion
model
Newly launchedantidepressant drugs in 15
countries (1987–1993)
APPENDIX AContinued
Marketing of the Life Sciences / 19
AuthorsDecision
Areas Main FindingsConceptualFramework
MethodUsed Empirical Base
DeSarbo et al.(2001)
GMET The specialist-physician population can be split into threesegments with respect to the stage of adoption of innovations in a
therapeutic category.
Marketinformationmapping
Latent structurespatial model
Top 7 brands prescribedamong 258 specialists
Shankar,Carpenter,andKrishnamurthi(1999)
GMET Growth-stage entrants reach their asymptotic sales level fasterthan pioneers or mature-stage entrants. They are not hurt by
competitor diffusion and enjoy a greater response to perceivedproduct quality than pioneers and mature-stage entrants.
Pioneers reach their asymptotic sales levels more slowly thanlater entrants. Mature-stage entrants are most disadvantaged.
Buyers are most responsive to pioneer marketing efforts.
New productgrowth
Dynamic brandsales model
29 ethical brands in 6therapeutic areas (1970s,
1980s)
Shankar,Carpenter,andKrishnamurthi(1998)
GMET Compared with pioneers or noninnovative late movers, innovativelate movers can create a sustainable advantage by enjoying
higher market potential and higher repeat purchase rates. Theygrow faster than the pioneer, slowing the pioneer’s diffusion and
reducing the pioneer’s marketing effectiveness. They areadvantaged asymmetrically; their diffusion can hurt other brands’
sales, but their sales are not affected by competitors.Noninnovative late movers face smaller potential markets, lowerrepeat rates, and less marketing effectiveness than the pioneer.
New productgrowth
Generalization ofthe Bass diffusionmodel for brand
sales
13 ethical brands in 2 chronicailment therapeutic categories
(1970s, 1980s)
Shankar (1997) GMET A pioneer that adopts a follower (leader) role with respect to amarketing-mix variable in a static (growing) market and witnesses
a decrease (increase) in own elasticity and margin after a newentry should accommodate (retaliate) in that variable.
New productgrowth
Game theory Full category of chronic careethical drugs (1970s, 1980s)
Therapy PromotionChintagunta and
Desiraju(2005)
SFM There is considerable heterogeneity in preferences and marketresponse for pricing and detailing across markets, which favors aregional approach to strategy. The effects of within- and across-
market interactions vary across markets and across brands withina market.
Competitivemarketing-mix
interactions
Category sales andmarket share
model
Antidepressant sales(1988–1999)
Wosinska(2005)
CM, SPC The impact of DTCA on patient compliance is small in economicterms, the effect spills over to other brands, and in certain cases
the effect may decrease average compliance rates.
Compliancebehavior
Negative binomialmodel
Panel of 16,011 patients,123,736 gaps between
prescriptions (1996–1999)
APPENDIX AContinued
20/ Journal of M
arketing,July 2009
AuthorsDecision
Areas Main FindingsConceptualFramework
MethodUsed Empirical Base
Bowman,Heilman, andSeetharaman(2004)
CM,SPC
Mindfulness is a predictor of patient compliance. Patients aremost at risk for noncompliance right after and some duration aftera medical treatment. Satisfaction with efficacy is a better predictor
of compliance than satisfaction with side effects or costs.Advertising shows a mixed influence. Direct channel shoppers are
more compliant than indirect channel consumers.
Compliancebehavior
OLS regressionand Tobit models
6238 patients making 44,345purchases (2001–2002)
Manchanda,Rossi, andChintagunta(2004)
SFM High-volume physicians are detailed to a greater extent than low-volume physicians without regard to responsiveness to detailing.Unresponsive but high-volume physicians are detailed the most.
Prescriptionbehavior
HierarchicalBayesian
estimation ofnegative binomial
model
Monthly prescription volume of1000 U.S. physicians for one
drug, the name of which is notrevealed (1999–2001)
Narayanan,Desiraju, andChintagunta(2004)
SFM,CM
DTCA and detailing affect pharmaceutical demand synergistically.Detailing raises price elasticity and has a higher return on
investment than does DTCA. The interaction between price anddetailing is negative. DTCA has a significant effect on categorysales, but detailing does not. Both detailing and DTCA affect
brand shares, and detailing has a much greater effect than DTCA.
Prescriptionbehavior
Category sales andmarket share
model
Monthly antihistamineprescriptions in the United
States (1993–2002)
Gönül et al.(2001)
SFM Physicians show fairly limited price sensitivity. Detailing andsamples have a mostly informative effect on physicians.
Physicians with a relatively large number of Medicare or healthmanagement organization patients are less influenced by
promotion than other physicians.
Prescriptionbehavior
Latent classmultinomial logit
model
1785 patient visits to 157physicians in the United States
for a chronic conditioncommon among the elderly
(1991–1994)
Ahearne, Gruen,and Jarvis(1999)
SFM Perceived salesperson attractiveness has a significant, positiveeffect on salesperson performance, but the effect diminishes asthe length of the salesperson–physician relationship increases.
Attractiveness leads to higher levels of perceived communicationability, likability, expertise, and trustworthiness.
Socialpsychology
Regressionanalysis on survey
data
339 U.S. physicians
Dekimpe andHanssens(1999)
SFM,CM
Strategic scenarios (business as usual, hysteresis in response,escalation, and evolving business practice) have a major impact
on marketing effectiveness and long-term profitability. Multivariatepersistence measures are proposed to identify which of four
scenarios is taking place.
Marketingstrategy
response
Vectorautoregressive
models
Monthly sample of five yearsfor a pioneering and
challenger brand in onepharmaceutical category in the
United States
APPENDIX AContinued
Marketing of the Life Sciences / 21
APPENDIX AContinued
AuthorsDecision
Areas Main FindingsConceptualFramework
MethodUsed Empirical Base
Hahn et al.(1994)
CM Effectiveness of communication on product trial is related mainlyto product quality and market growth. Effectiveness of word of
mouth is associated with product class characteristics and marketcompetitiveness. The effect of product trial on repeat purchases isrelated to product quality and market characteristics, such as size,
growth, competitiveness, and familiarity.
New productgrowth
Four-segment trial-repeat model
21 ethical drugs in 7therapeutic categories,
launched from 1981 to 1984
Mantrala, Sinha,and Zoltners(1994)
SFM The agency theoretic model–based approach can assistmanagement in evaluating and optimally structuring multiproduct
sales quota bonus plans.
Agency theory Utility model onconjoint data
12 sales people in a singlecompany
Parsons andVandenAbeele (1981)
SFM Sales call elasticity varies over time as a function of the collateralmaterial (samples and handouts).
Marketingstrategy
response
OLS regressionmodel
Monthly sales for anestablished drug within the
steroid group of prophylacticmedicines for women inBelgium (1973–1974)
Notes: Decision areas: CM = communication management, GMET = global market entry timing, IAF = innovation alliance formation, SFM = sales force management, SPC = stimulating patientcompliance, TP = therapy positioning, and TPO = therapy pipeline optimization. Note that no research was published (yet) on key opinion leader selection in the five major marketing jour-nals we studied.
22/ Journal of M
arketing,July 2009
Authors Main FindingsConceptualFramework Data Type Empirical Base
Berger andRand (2008)
In the context of alcohol and junk food consumption, associating risky healthbehavior with a social identity people do not want to signal can lead consumers
to make more healthful choices.
Health-relatedbehavior
Experiments 50 undergraduate students87 resident college students
75 college students
Bolton et al.(2008)
Consumer belief that a drug alone will take care of a health risk creates aboomerang effect in drug marketing by undermining intentions to engage inhealth-protective behavior. This is because (1) drugs reduce risk perceptions
and perceived importance of complementary health-protective behavior, as wellas the motivation to engage in such behavior, and (2) drugs are associated with
poor health, which reduces self-efficacy and perceived ability to engage incomplementary health-protective behavior. A combined intervention
accompanying a drug remedy that targets both motivation and ability mitigatesthe drug boomerang on a healthful lifestyle.
Healthcommunication
and health-related
behavior
Experiments 185 patients at risk of highcholesterol
81 staff and college students213 staff and college students
Hong and Lee(2008)
Regulatory fit, experienced when a person’s strategy of goal pursuit fits with hisor her regulatory focus (promotion or prevention based), enhances self-
regulation toward desirable outcomes through intensified motivation. Regulatorynonfit impairs self-regulation by reducing motivation.
Health-relatedbehavior
Experiments 48 undergraduate students64 university participants
182 MBA students228 undergraduate students
Riis, Simmons,and Goodwin(2008)
An examination of the willingness of young, healthy people to take drugsintended to produce psychological enhancement found that people were much
more reluctant to enhance traits believed to be more fundamental to self-identity(e.g., social comfort) than traits considered less fundamental to self-identity
(e.g., concentration ability). People were more inclined to ban enhancementsthat were morally unacceptable.
Health-relatedbehavior
Experiments 357 undergraduate students176 undergraduate students90 undergraduate students
359 undergraduate students500 participants ages 18–45
Wong and King(2008)
Risk understanding in the context of breast cancer is influenced by the dominantillness narrative of restitution within Anglo-Western cultures. Restitution storiesreflect the cultural values of personal responsibility and taking control in fighting
disease and returning to a normal life. Restitution promotes early detection,aggressive treatment, and reconstructive surgery as concealment. This riskunderstanding contributes to the consumption of health care interventions
exceeding U.S. medical guidelines.
Health riskperception
Phenomeno-logical
interviews
12 participants diagnosed withbreast cancer
Agrawal,Menon, andAaker (2007)
When people are primed with a positive emotion (e.g., happiness,peacefulness), the compatibility between the referent and the discrete emotion
fosters the processing of health information. When the primed emotion isnegative (e.g., sadness, agitation), compatibility hinders processing of the
message.
Healthcommunication
Experiments 80, 103, 188, and 98undergraduate students
APPENDIX BOverview of Health Psychology Literature
Marketing of the Life Sciences / 23
APPENDIX BContinued
Authors Main FindingsConceptualFramework Data Type Empirical Base
Bolton, Cohen,and Bloom(2006)
Remedy (e.g., smoking cessation aids) messages undermine risk perceptionsand increase risky behavioral intentions as consumer problem status rises (i.e.,
among those most at risk).
Healthcommunicationand health risk
perception
Experiments 97 college students99 people
72 university/hospital staff andstudents
Keller (2006) A person’s regulatory focus determines the salience of self-efficacy (perceivedease) or response efficacy (perceived effectiveness) of health behaviors. There
are greater regulatory–efficacy fit and higher intentions to perform theadvocated behaviors when self-efficacy features are paired with promotion focus
and when response efficacy features are paired with prevention focus. Self-efficacy is weighed more than response efficacy when the regulatory focus is
promotion, whereas the reverse is true in prevention regulatory focus.
Health-relatedbehavior
Experiments 60 undergraduate students61 middle school adolescents
Thompson(2005)
Dissident health risk perceptions are culturally constructed in the natural-childbirth community, are internalized by consumers as a compelling structure of
feeling, and are enacted through choices that intentionally run counter toorthodox medical risk management norms.
Health riskperception
Phenomeno-logical
interviews
10 couples of a natural-childbirth community
Chandran andMenon(2004)
Everyday, health hazard framing makes risks appear more proximal andconcrete than every-year framing, resulting in increased self-risk perceptions,intentions to exercise precautionary behavior, concern and anxiety about the
hazard, and effectiveness of risk communication.
Healthcommunicationand health risk
perception
Experiments 46, 64, and 153 undergraduatestudents
Dellande, Gilly,and Graham(2004)
In the context of a weight-loss clinic, provider expertise and attitudinalhomophily play a role in bringing about customer role clarity, ability, and
motivation. Compliance leads to goal attainment, which results in satisfaction.Compliance also leads to satisfaction directly; consumers who comply with
program requirements have greater satisfaction with the program.
Health-relatedbehavior
Survey,archival data,
andinterviews
376 patients and 36 nurses inSouthern California
Moorman et al.(2004)
Subjective knowledge (i.e., perceived knowledge) can affect the quality ofconsumers’ choices by altering where consumers search. Subjective knowledge
increases the likelihood that consumers will locate themselves proximal tostimuli consistent with their subjective knowledge. As such, subjectiveknowledge influences choice by affecting search selectivity between
environments rather than search within the environment. The need for self-consistency drives the effect of subjective knowledge on search.
Healthcommunication
Experimentsand survey
44 people212 undergraduate students947 shoppers in 20 product
categories
Thompson(2004)
In the natural health marketplace, a nexus of institutional, competitive, andsociocultural conditions engenders different ideological uses of this marketplace
mythology by two types of stakeholders: advertisers of herbal remedies andconsumers seeking alternatives to their medical identities.
Healthcommunication
Ethnographicstudy
3 advertisements for naturalhealth products
24/ Journal of M
arketing,July 2009
APPENDIX BContinued
Authors Main FindingsConceptualFramework Data Type Empirical Base
Kahn and Luce(2003)
Given a false-alarm result, life-threatening test consequences are associatedwith more disutility for future testing than when test consequences are less
significant. This does not hold for normal test results. Patients receiving a false-alarm result experienced more stress, were less likely to believe that a positive
mammography result indicated cancer, and were more likely to delaymammography than patients receiving normal results, unless they were also
told that they may be vulnerable to breast cancer in the future. Delays inplanned adherence following a false-alarm result can be mitigated by an
information intervention.
Health-relatedbehavior and
health riskperception
Experiments 64 women in a universityhospital mammography waiting
room
Keller, Lipkus,and Rimer(2003)
In the context of a message on breast cancer risk, people induced with apositive mood are more persuaded by the loss-framed message (the cost of not
getting a mammogram), whereas people induced with a negative mood aremore persuaded by the gain-framed message (the benefits of getting a
mammogram). People in a positive mood have higher risk estimates and lowercosts in response to the loss frame than the gain frame, whereas the reverse is
true for people in a negative mood.
Healthcommunicationand health risk
perception
Experiments 85 women between the ages of40 and 70
124 women between the agesof 40 and 70
Spangenberget al. (2003)
Self-prophecy through mass-communicated prediction requests can influencenormative behaviors for large target populations.
Healthcommunication
Experiments 72 undergraduate students1665 health and fitness club
members202, 74, and 92 undergraduate
students83 university staff members
Keller, Lipkus,and Rimer(2002)
Compared with nondepressives, depressives lower their risk (of getting breastcancer) estimates such that they are more accurate or closer to the medical
estimates provided in risk feedback. Nondepressives with higher baseline riskestimates do not revise their follow-up risk estimates, because they are in a
positive mood after receiving the risk feedback.
Health riskperception
Experiments 55 women between the ages of40 and 60
74 women between the ages of25 and 40
Menon, Block,andRamanathan(2002)
Message cues can reduce self-positivity bias (i.e., the tendency for people tobelieve that they are invulnerable to disease) and engage people in more
precautionary thinking and behavior. Risk behavior cues in the message affectpeople’s estimates of their vulnerability (self-risk estimates), depth of message
processing, attitudes, and behavioral intentions.
Healthcommunicationand health risk
perception
Experiments 137, 110, 160, and 152undergraduate students
Thompson andTroester(2002)
Natural health consumers use narratives to articulate the values manifested intheir wellness-oriented consumption outlooks and practices. Narratives reveal
the meaning-based linkages between these articulated values and theconsumption goals being pursued through natural health practices.
Healthcommunication
Phenomenological
interviews
32 natural health consumers
Marketing of the Life Sciences / 25
Authors Main FindingsConceptualFramework Data Type Empirical Base
Luce and Kahn(1999)
In the context of chlamydia and mononucleosis, false-positive outcomesincrease perceptions of vulnerability and test inaccuracy, even when test-errorbase rates are held constant. Increased perceived vulnerability appears to bedirectly related to the testing event because the effects are not replicated bysimply asking participants to imagine having the malady. False-positive test
results increase planned compliance if there are poor alternatives to testing or ifthe value of test-initiated treatment is high, but they do not affect compliance if
good testing alternatives are available or if the treatment value is low. Theresults of a false-positive outcome on compliance are partially mediated by
changes in perceived vulnerability and test accuracy.
Health-relatedbehavior
Experiments 152, 49, and 129undergraduate students
Raghubir andMenon(1998)
In the judgment of the risk of contracting AIDS, the perceived similarity ofanother person and the ease with which related information can be retrieved
from memory moderate self-perceptions of risk in an absolute sense and reducethe self-positivity bias. Increasing the accessibility of a cause of AIDS—for
example, in an advertisement propounding safe sex—increases perceptions of aperson’s own risk of contracting AIDS, reduces the self-positivity bias, leads to
more favorable attitudes and intentions toward practicing precautionarybehaviors, and leads to deeper processing of AIDS educational material.
Health riskperception andhealth-related
behavior
Experiments 28, 76, 109 undergraduatestudents
Keller andBlock (1997)
There is an inverted U-shaped relationship between resource allocation andpersuasion for vivid information and a positive linear relationship between
resource allocation and persuasion for nonvivid information when vividinformation is less resource demanding than nonvivid information. When
nonvivid information is less resource demanding than vivid information, there isan inverted U-shaped relationship for nonvivid information and a positive linearrelationship for vivid information. The contrasting persuasion functions for vividand nonvivid information can predict when vivid information will be more versus
less persuasive than nonvivid information.
Healthcommunication
Experiments 120 graduate andundergraduate students
94 undergraduate studentsmokers
190 undergraduate students
Keller andBlock (1996)
In the context of messages prompting smoking cessation, when a low level offear is ineffective, it is because there is insufficient elaboration of the harmful
consequences of engaging in the destructive behavior. When appeals arousinghigh levels of fear are ineffective, it is because too much elaboration on the
harmful consequences interferes with processing of the recommended changein behavior.
Healthcommunication
and health-related
behavior
Experiment 97 university students smokers
APPENDIX BContinued
26/ Journal of M
arketing,July 2009
Authors Main FindingsConceptualFramework Data Type Empirical Base
Block andKeller (1995)
In the context of skin cancer and sexually transmitted diseases, the authorsshow that a low-efficacy condition (i.e., when it is uncertain that following therecommendations will lead to the desired outcome) motivates more in-depth
processing. When participants engage in in-depth processing, negative framesare more persuasive than positive ones. A high-efficacy condition generates
less effortful message processing when positive and negative frames areequally persuasive.
Healthcommunication
Experiments 94 undergraduate students115 students
Moorman andMatulich(1993)
The interaction of health ability with health motivation affects consumers’ healthbehaviors. The impact of these characteristics depends on the particular health
behavior and the specific health ability characteristic.
Health-relatedbehavior
Experiment 404 consumers
Friedman andChurchill(1987)
In the context of health care delivery, the effectiveness of expert and legitimatesocial power behaviors—in terms of patient satisfaction, compliance, andaction—is contingent on the aspect of the situation that is manipulated.
Conversely, high-referent and low-coercive power are preferred by patientsregardless of the situation.
Health-relatedbehavior
Experiment 396 female graduate students
Burnett andOliver (1979)
Response to fear appeals is specific to the situation, topic, person, and criterion.This supports segmenting target consumers by demographic or psychographic
traits in the use of fear appeals.
Healthcommunication
and health-related
behavior
Experiment 1600 people served by a healthmanagement organization
Oliver and Berger(1979)
Health belief models incorporating evaluative components, normative influences,emotional factors, and intervening summary concepts may yield a greater
understanding of health care decisions.
Healthcommunication
Experiment 332 students and 469 residents
APPENDIX BContinued
Marketing of the Life Sciences / 27
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