A patent grants its holder the right to exclude others from producing or using the underlying invention (e.g. [23] [24] ) and thus, protects a firm’s technological assets [11] . The protection is guaranteed for a limited period of time, usually twenty years [24] . During the time of protection, patents provide a competitive advantage for firms through the possibility of offering distinctive products or services, exploiting cost advantages or generating revenues from licensing activities [18] [25] [26] . However, the protection of technology through patents is associated with certain tangible and intangible costs (see e.g. [27] [28] ). Whereas the tangible component consists of costs for the filing and defense of patents, the intangible part is related to the costs of information disclosure (see e.g. [27] [28] ). Consequently, a firm will only decide to file a patent if the possible benefits resulting from the protection mechanism exceed the costs for filing the patent [27] [29] .

In prior research, differences in the patenting behavior―meaning the intensity of as well as the reasons for patenting―across industries have been shown. Several studies have suggested that patents may be more important for industries such as pharmaceuticals and chemicals [30] , whereas they are considered of less value in, for instance, software and internet industries [16] . Reference [25] has differentiated between discrete―such as chemicals―and complex industries―such as semiconductors―and investigated the underlying reasons for patenting. In the former, patents are used for defensive purposes whereas in the latter mainly for offensive reasons. Furthermore, the patenting behavior differs among service and manufacturing firms whereby patents are considered more important for the latter [31] . Nevertheless, not only industry characteristics influence patenting decisions, firm size has proven to be of similar importance. Several studies have identified patent intensity as being positively related to firm size (e.g., [10] [31] [30] [32] ). The focus of this study, however, is on small firms―more specifically on small and new firms―namely start-ups.

Some of the benefits resulting from patenting show similarities between start-ups and larger firms. These involve mainly competitive advantages, preventing others from copying technology, and enhancing reputation (see e.g. [16] [25] ), whereby the latter may be particularly important for start-ups [16] . Reference [15] considers a patent as “important asset that provides protection from imitation or a basis for contracting in the market for technology” for start-ups. Reference [25] has a similar view. They regard patents as facilitating negotiations with other firms by strengthening start-ups’ positions.

Although patents provide several benefits for start-ups, the costs associated with the filing of patents are more likely to affect them, since they are typically constrained in terms of capital and staff. First, the direct costs related to the patenting process estimated at about USD 20,000 [29] may be regarded as a considerably high amount for start-ups [18] . Furthermore, they often lack resources needed for defending their patents [25] [33] ―including monitoring possible violations and litigating in the case of infringement. Another important issue is the absence of funded knowledge regarding legal issues which is particularly crucial for defending a firm’s IP [18] .

Once start-ups have made the decision to patent, however, they typically exhibit better characteristics than their non-patenting peers. Several studies have revealed a positive correlation between patenting and subsequent performance. First, patenting activity has been found to increase firm survival [9] [33] [34] [35] . Second, it has been identified as being positively related to the probability of issuing initial public offerings (IPOs) [6] [7] . Third, [33] had found patenting to enhance growth rates. Another important aspect is the positive effect of patenting on subsequent firm valuation [18] [36] .

While patents are strongly related to a company’s technology base and therefore to its research and development (R & D) activities, trademarks are connected to marketing activities [37] . A trademark is defined as a “distinctive sign which identifies certain goods or services as those produced or provided by a specific person or enterprise” [24] . It can be a word, name, phrase, symbol, or logo [38] [39] . In contrary to patents, the protection provided by trademarks can be perpetuated permanently [24] [28] . This creates the possibility to realize profits from an innovation after the initial protection by patents has expired [40] . The main benefit from filing trademarks is that it enables firms to differentiate their products from those of their competitors [35] [41] [42] and so, allows them to indicate “a certain level of quality or other characteristic” [35] . Thus, trademarks help to reduce consumer search costs [37] [42] . However, while a patent results in competitive advantages immediately after the grant decision, the benefits resulting from trademark filing require providing consistent quality of the product or service protected by the trademark [42] and will only be developed over time [11] .

Extant literature has suggested trademarks as being more widely applicable than patents since their usefulness is not restricted primarily to manufacturing sectors (e.g. [35] [38] [43] ). Furthermore, a major advantage of filing trademarks is that the application process is associated with less necessary resources. First, applying for a trademark is considerably cheaper than applying for a patent [38] [44] . Second, filing a trademark does not require a technological breakthrough like a patent [38] and the subsequent grant decision is less risky―meaning it is more likely to receive a grant decision for a trademark than for a patent. Patent eligibility requires that the underlying innovation is novel and non-obvious, whereas in the case of trademarks only the criterion of distinctiveness needs to be met [45] . These characteristics may make trademarks especially suitable for small firms.

Besides the lack of financial resources, their newness is a major challenge for start- ups [3] . New firms are usually unknown to potential customers and as a result, they often have to face a lack of trust in their new products or services [3] . Therefore, investing in marketing in order to finally start establishing identity and with it a brand seems to be pivotal to subsequent success [3] . In this process, trademarks can be regarded as fundamental for effective commercialization and diffusion of start-ups’ innovations [11] [35] .

Similar to patenting start-ups, trademarking start-ups exhibit several positive characteristics compared to their non-trademarking peers. Although literature on the interrelation of start-ups’ trademarking behavior and their subsequent performance is relatively scarce, a positive effect of trademarking on survival [35] as well as on asset growth has been identified [33] . However, it is important to notice that trademarking only relates to subsequent performance as an indicator of innovation. This means, innovation leads to performance improvements―with trademarking being its measure― and not the mere fact of trademarking alone.

As indicated above, VCs are substantially involved in businesses of the companies they finance [11] [19] [46] . In order to increase the likelihood of success and rise their return on investment VCs take various measures―such as setting milestones [8] [11] [22] or staging capital injection [46] [47] . However, VCs do not merely monitor the businesses they finance, but they also provide advice and expertise [4] [10] [19] [12] . A rather broad body of research has investigated the potential benefits provided by VCs. For instance, [48] regards VCs as “value-added investors” that allocate benefits that excess the sole supply of financial resources. Rather they assist young firms in developing strategies [10] [11] [19] . By doing so, they provide support for making decisions regarding marketing [12] , financing, budgeting and human resource (HR) issues [10] . Reference [3] , for instance, regards especially insufficient marketing knowledge as major obstacle for the success of start-ups. Owing to their experience, VCs can usually compensate that lack of knowledge and set start-ups on the right track. Furthermore, VCs may speed up start-ups’ development processes [19] and, hence, promote professionalization [22] . An evident sign for a start-up’s professionalization progress is the recruitment of senior management [19] . Typically, venture-backed start-ups earlier recruit outside chief executive officers (CEOs) [22] which make the influence of VCs on the professionalization process apparent. Another indicator of start-ups’ development stages is the launch of products on the market [3] . In this context, [19] had identified venture-financed start-ups as being faster in bringing products to the market

Besides the direct influence on start-ups’ strategies, VCs have been found to provide further benefits. Due to their newness start-ups usually do not exhibit a sound level of reputation [3] [49] which is essential for establishing relationships with customers and suppliers in order to successfully achieve market entries [3] [50] . VCs can help to overcome this challenge by providing forms of certifications regarding the quality of the financed companies [8] [48] [49] . The importance of certification for start-ups has been demonstrated by, for instance, [49] who has shown that financing offers by VCs with high reputation are much more likely to be accepted by start-ups than offers from VCs with a lower degree of reputation. Another proof of VCs’ certification effect and its relevance for start-ups is the increase of coorporative behavior after having received VC financing [50] . However, in the context of entering into cooperations, the intermediation function of VCs plays an equally important role. VCs often have large networks [4] [8] and consequently, can help start-ups find appropriate partners [26] [50] . Furthermore, VCs can help start-ups to acquire additional capital in later stages [46] [49] . A considerable avenue of research has also identified a positive correlation between receiving VC financing and subsequent performance. Start-ups being venture-backed have increased likelihoods of IPOs [50] as well as higher valuations at the time of IPOs [51] . Additionally, start-ups often exhibit a remarkable growth in size after receiving VC financing [52] [53] .

Since this paper seeks to shed light on the changes in start-ups’ patent and trademark portfolios after VC investments both literature on the role of patents and trademarks before and after VC investments have been investigated. The literature in this context can be divided into two major streams―the signaling value of patents and trademarks before VC financing and the influence of said investments on the underlying portfolios.

As indicated above, start-ups face various obstacles when seeking external finance resulting from substantial information asymmetries between them and their potential financiers [1] . Since they cannot display major revenues [14] ―especially in their early stages―VCs need to examine other factors that may indicate start-ups’ expected values (see also [14] [54] [55] ). One such indicator might be the scopes of start-ups’ patent portfolios which hence, can be regarded as signals for their quality [14] [18] [54] .

In signaling theory, a signal is sent by the better informed party―the start-up―to the less informed party―the VC [56] ―resulting in a potential reduction of information asymmetries between those two parties [57] . In order for the sent information to be regarded as signal, two requirements need to be met―it has to be observable and costly [56] . The criterion of observability is obviously fulfilled both in the case of patent [29] and trademark filings. The requirement of the signal being costly is also met. The filing of patents is associated with direct costs of up to USD 20,000 [29] and various further costs of indirect nature―such as costs associated with the disclosure of information [27] [28] [29] . The filing of trademarks involves considerably less direct costs [38] [44] . Nevertheless, it is related with substantial further efforts since it requires careful thought about the desired perception of the firm by its consumers. Since start-ups in their early stages are not only unknown to capital providers but also to potential customers [3] , they need to think even more carefully about the image their trademarks shall convey. Finally, the interpretation of a signal helps its receiver to draw conclusions about a characteristic which is difficult or impossible to observe [56] [57] . In the context of start-up financing, VCs can examine IP portfolios (the signal being the filing of IPRs) in order to deduce estimations of start-ups’ expected values [14] [18] [20] [54] .

Particular evidence for the relevance of patenting activity in reducing information asymmetries between start-ups and VCs is provided by [7] who have shown that patenting intensity increases with rising information asymmetry. Reference [18] has revealed similar interrelations. They have found the signaling value of patents as being greater in earlier funding rounds when information asymmetries are most incisive. Various studies regard patent activity as conveying information on the expected performance of start-ups [14] [18] [20] [54] . In order for an invention to be patentable three requirements need to be fulfilled: it needs to be new, non-obvious and useful [28] . The criterion of usefulness implies that there exists a market niche for the underlying innovation. Since a company will only file a patent in case they expect a positive grant decision, a company’s decision to do so suggests that they have detected a market niche for their technology [58] . Additionally, [15] consider patents as reflecting the value of firms’ technologies, meaning firms having technologies of higher qualities obtain more patents, and therefore are more attractive to potential investors. Moreover, being able to “stake technological claims” [59] ―which is achieved by filing patents―can signal start-ups’ future potential [59] which further supports the findings of [15] . Furthermore, [54] has underpinned the relevance of patents’ signaling value for new ventures by revealing that start-ups decide to file for patents in order to signal their quality to potential investors. On the other hand, patents can also carry additional information other than those related to technological quality [58] . Such information can include the quality of start-ups’ managements [9] [15] [58] and start-ups’ stages of development [58] .

A considerable body of research has succeeded to prove that the signaling function of patents is actually valued by VCs. First, patenting start-ups are more likely to receive VC funding. Reference [15] have conducted a study among U.S. software start-ups and found that patenting is positively related to the probability of receiving VC financing. Analyses of [14] [16] [17] [18] [19] have shown similar results, although in different settings regarding industry and region. Furthermore, patent filings have been found to positively affect the probability of attracting prominent VCs [18] . In addition, patenting activity influences the time to first VC funding. Patenting start-ups receive their first VC funding substantially earlier than their non-patenting peers [14] [19] . In this context, the number of patents as well as their quality positively affects the timing of first VC funding [14] . Finally, patenting activity has been identified as positively influencing the amount of VC financing [7] [9] [20] .

Contrary to the signaling value of patents, there is no broad body of research on the signaling value of trademarks in VC financing. References [3] [60] and [61] have suggested that VCs positively value the market orientation of start-ups. Since trademarks are important means to protect marketing assets, the filing of those is likely to reveal information on start-ups’ market orientation [62] . Reference [44] has further argued that trademarks are closely related to innovation in small firms, mainly due to substantially lower costs compared to patents making them more suitable for small firms (see also [38] ). Taken together, one can argue that VCs value trademarks as signals for start- ups’ technology quality and market readiness. However, to the best of our knowledge, only [21] have analyzed the signaling value of trademarks so far. They have found a positive relation between trademarks and subsequent valuation by VCs which provides support for the reasoning above.

The second relevant stream of literature addresses the converse case―meaning the influence of VCs on start-ups’ patent and trademark portfolios. Only few researchers have examined these possible interrelations in the context of patenting. Reference [12] has investigated the patenting behavior of venture-backed U.S. start-ups across five manufacturing sectors. VC funding appears to positively influence patenting intensity, nevertheless, a slowdown in patenting during the first year after the funding round has been observed. However, they have primarily focused on the question if VC funding promotes innovation or if rather the opposite is the case. Furthermore, [10] has compared the patenting rates of 351 Italian venture-backed (33) and non-venture-backed start-ups (318) active in high-technology manufacturing industries and software between 1994 and 2003. According to their analysis, receiving VC funding is accompanied with a significantly higher propensity to patent. Furthermore, it leads to increased patenting intensity. However, it is important to recognize that the VC industry in Europe is still in its early stages―especially compared to the U.S. or Israel [10] . When additionally considering the small number of venture-backed start-ups in their sample, their findings may be only of limited informational value. Another study, focusing on the U.S., has been conducted by [13] . They have investigated the influence of VC funding on patented inventions by comparing 122 venture-backed and 408 non-venture-backed start-ups across twenty manufacturing industries between 1965 and 1992. However, they have prioritized the question whether VC funding promotes innovation and regarded increased patenting activity as the mere outcome of the same. Consequently, their findings have indicated a positive impact of VC financing on innovation. In fact, venture capital has been found to be 40 times as potent as R & D. Furthermore, venture-backed firms are generally more likely to patent and their patents exhibit better qualities―with patent quality measured by citations. Nevertheless, further shedding light on the effect of VC funding on subsequent patenting activities of U.S. start-ups would be a noteworthy contribution to extant literature.

Regarding trademarks, there seems to be only one study investigating the impact of VC funding on start-ups’ subsequent trademarking activity. The dataset of the study conducted by [11] consists of 4703 U.S. start-ups operating across six industries that filed their first IPR between 1998 and 2007. Their analysis has revealed that venture- financed firms are more likely to file a trademark than a patent as first IPR.

However, there is, to the best of our knowledge, no study jointly examining the impact of VC funding on trademark and patent portfolios. Therefore, comparing trademark portfolios before and after VC financing is another important contribution to literature related to the interface between entrepreneurial financing and IP.

Two major factors point to a rise in the number of patents filed after VC funding. The literature on the importance of patents as quality signals to VCs implies that start-ups already have obtained patents before first VC funding. Nevertheless, start-ups face challenges which probably hamper the filing of patents. First, start-ups often lack specific knowledge of the protection the IPR system can provide [63] which may prevent them from filing patents. Furthermore, they may lack both knowledge [18] and resources in form of capital and staff which are required to defend their patents [25] [33] . VCs, however, are usually able to provide support in terms of financial resources and legal knowledge for the filing and defending of start-ups’ patents [9] . Second, extant literature suggests that VCs promote professionalization of the start-ups they finance [22] . Reference [22] has based professionalization on criteria such as formulation of HR policies and the recruitment of outsiders as CEOs. In contrast, we extend professionalization to the filing of IPRs. In case of patens, this assumption appears reasonable since the filing of these shows that firms have recognized the need to protect their technology in order to successfully master the challenges of launching new products and services. Taken together, we assume that VCs will promote the filing of IPRs in form of patents. Specifically, we expect a rise in the number of patent applications after a start-ups’ first funding round.

Thus, the following hypothesis is formulated:

Hypothesis 1: The first funding round leads to an additional number of patent applications.

Regarding the filing of trademarks, we have similar assumptions. According to [60] [61] , VCs regard marketing as crucial for the success of start-ups. In fact, they rank the importance of marketing higher than all other business functions. Since start-ups often lack sufficient experience exactly in that field [3] , they need the expertise that VCs typically can provide. Furthermore, VCs set milestones related to the introduction of products and services on the market in order to shift start-ups’ focus towards commercialization [11] [19] [22] . “Trademarks are an important tool in establishing the communicative link to consumers” [11] and therefore the filing of those can be regarded as one of the initial steps in the commercialization process of innovations. Since VCs aim at speeding up the commercialization of start-ups’ products and services we shall argue that VC funding is accompanied by a rise in the number of trademark applications.

The following hypothesis is formulated accordingly:

Hypothesis 2: The first funding round leads to an additional number of trademark applications.

We do not only expect a change in the scope of start-ups’ IP portfolios after VC funding, but we also assume a change in their compositions―meaning the share of patents and trademarks within the portfolios. VCs usually have a limited time span devoted to each start-up within which they invest and then expect making first profits [4] [46] [64] . They usually decide to invest in ventures which they regard as being able to become profitable within reasonable time and with reasonable capital [8] . This implies that “VCs are not interested in funding basic research” [8] . Rather they aim at, as aforementioned, shifting start-ups’ focus towards the commercialization of their innovations [11] [19] . This has been further confirmed by [22] who have found out that venture-backed start-ups have a significantly shorter time-to-market than their non- venture-backed peers. Since trademarks play an important role in the initial stages of the commercialization process, a considerable impact on the application of trademarks can be expected. We assume that VCs may promote the filing of trademarks as an initial step in the commercialization process more intensely than the filing of additional patents. Consequently, the share of trademark applications compared to patent applications in start-ups’ IP portfolios after the first funding round should increase or, in other words, the number of additional trademark applications after the first funding round is expected to be higher than the number of additional patent applications.

This assumption is expressed in the following hypothesis:

Hypothesis 3: The first funding round leads to more additional trademark applications than additional patent applications.

Furthermore, we shall argue that the effects described in section 3.1 are observable throughout the whole venture cycle, although their intensities vary. In the underlying model, the progress through the venture cycle is approximated by the number of funding rounds. Reference [9] have, among other criteria, also used the number of funding rounds as proxy for the progress through the venture cycle, meaning with each subsequent funding round start-ups proceed along the venture cycle.

The relationship between VCs and the start-ups they finance is of ongoing nature, meaning that VCs usually invest repeatedly in the same start-up [47] . Consequently, they continuously monitor and advise the management, among others, on IP issues. We therefore assume that each funding round has an impact on the numbers of patent and trademark applications―meaning a supplementary funding round results in additional applications of patents and trademarks. However, we further expect that these effects will vary when start-ups proceed along the venture cycle.

As aforementioned, VCs provide support in terms of expertise and capital for the filing of patents in order to protect a start-up’s existing technology base [9] [12] and promote start-ups’ professionalization [22] . However, we do not expect them to particularly aim at enhancing further R & D resulting in additional patentable technologies which is similar to the assumptions of [8] . Furthermore, the signaling value of filing patent applications decreases once start-ups have succeeded in attracting VC funding. Even in the case of further capital requirements, the signaling value is expected to play a minor role since VCs can usually provide support here [46] [49] . Taken together, we expect the number of additional patent applications after subsequent funding rounds to decrease along the venture cycle.

This expectation leads to the following hypothesis:

Hypothesis 4: The number of additional patent applications decreases with the start- ups’ progress through the venture cycle.

Regarding the number of additional trademark applications, we have different expectations. As start-ups proceed along the venture cycle they leave the phase of developing new technologies and approach the commercialization of their products or services. As abovementioned, VCs purpose shifting the start-ups’ focus towards the commercialization of their innovations [11] [19] , which further promotes this process. Since trademarks are essential components within this development, there is reason to presume that VCs aim at enhancing start-ups trademarking activities while they proceed along the venture cycle. Hence, we assume that the number of additional trademark applications increases with each subsequent funding round.

The following hypothesis should thus hold:

Hypothesis 5: The number of additional trademark applications increases with the start-ups’ progress through the venture cycle.

The dataset for this analysis has been obtained from several sources. Investment data of VC-funded start-ups has been acquired from the VentureXpert database (see also e.g. [7] [9] [15] [11] ). Since this study is focused on the U.S. the data on trademark applications has been collected from the United States Patent and Trademark Office (USPTO). U.S. patent data has been gathered from the EPO Worldwide Patent Statistical Database (also known as PATSTAT). Then, patent and trademark portfolios have been created using a manual matching process based on the start-ups’ names.

Initially, 50,477 funding rounds of 26,209 U.S.¹-based venture-backed² start-ups have been retrieved from VentureXpert. The VentureXpert database does not provide any information on companies’ stages within the venture cycle. However, the exclusion of observations with funding round numbers greater than three seemed to be an appropriate way to ensure a focus on start-ups only. Cases with missing start-up founding dates have been dropped.³ Likewise, funding rounds with incomplete investor data have been excluded.⁴ Furthermore, funding rounds which featured probable inconsistencies regarding round date information have been deleted. These include observations with more than one round date for the same funding round of a company as well as cases in which funding has been acquired before a start-up’s founding date or rounds which are reported as having occurred after subsequent rounds. Finally, cases in which funding occurred more than ten years after a start-ups founding date⁵ have been dropped.⁶ These modifications lead to a dataset comprising 24,387 funding rounds of 13,896 U.S. venture-backed start-ups.

In the next step, the data on patents and trademarks⁷ have been adjusted. Since the trademark dataset has been retrieved from the USPTO it only covers U.S. trademarks. In order to preserve consistency, patent data has been restricted to the U.S. as well. Finally, the patent and trademark portfolios have been compiled in a manual matching process based on the start-ups’ names. In order to improve the measurability of VC funding on subsequent IP activities, only start-ups that have proven to be generally affine to applying for patents and trademarks have been examined. This means, only companies that applied for at least one patent and one trademark during the time of observation⁸ have been kept within the dataset.⁹ Hence, the underlying dataset comprises patent and trademark portfolios for 531 start-ups that received in total 1062 funding rounds between 1991 and 2009.

The two dependent variables of this regression analysis are the additional numbers of patent and trademark applications filed after VC funding rounds―new patent applications after round and new trademark applications after round. Using patent applications rather than grants is widely spread in research on IP activity (e.g. [11] [13] [18] ) since “they relate to the point in time at which the start-up made the strategic decision to obtain a specific type of IP” [11] . Moreover, ultimate patent grant decisions have been frequently reported as being of little importance in the context of VC funding (e.g. [7] [14] [15] ). Likewise, we also focus on trademark applications rather than registrations. In the further analysis of the quality of the newly filed patents a different dependent variable is used―new citation-weighted patents after round. This variable measures the number of citations the newly filed patents accumulative receive.

The major independent variables are binary variables for each funding round― round 1 dummy, round 2 dummy and round 3 dummy which equal one for round one, round two or round three respectively and otherwise 0. Furthermore, the number of patent and trademark applications before funding rounds are included―patent applications before round and trademark applications before round. Patent and trademark applications which are more than five years before a start-up’s founding date have not been counted.¹⁰ Additionally, a patent dummy variable and a trademark dummy variable are used. These allow distinguishing the effects of VC funding on the number of additional patent and trademark applications for start-ups that have not applied for any patents or trademarks prior to first funding from those having filed at least one application. Similar variables have been created for the above mentioned investigation of patent citations. Citation-weighted patents before round counts the number of citations of those patent applications that were filed before funding rounds. The citations dummy distinguishes start-ups whose patents¹¹ before first funding have no citations from those start-ups whose patents have. Additionally, the variables patent literature backward references and non-patent literature backward references represent the number of backward references in patent and non-patent literature, respectively.

The following control variables are included in the regression analysis. Start-up age (see also [11] [18] [21] ) represents the age in years of start-ups at funding. There is reason to assume that older start-ups already are further developed within their business cycle and therefore differ in their IP portfolios [65] . In order to control for differences in VC characteristics and influence, the number of investors of a particular funding round is included. VC age measures the time in years between a VC’s first investment and the date of the current funding round (see also e.g. [21] ). VC experience counts the number of investments a VC already has undertaken prior to the current funding round (see also e.g. [21] ). In case more than one VC invests in a specific funding round, the average values for age and experience are calculated. Furthermore, we control for the amount of funding. Since the underlying data does not provide information on the amount that a particular VC invests in a specific funding round, the amount that a VC invests in total in a start-up―total amount invested in start-up by VC is used instead. Again, in the case of a syndicate the mean value is calculated. Finally, six industry and six U.S. region dummies (see also e.g. [11] [21] ) are included in order to capture differences across industries [16] [25] [31] and regions. An overview of all variables of the regression is provided in Table 1.

This paper uses an event study to perform the underlying analysis (see also e.g. [66] ). An event study is usually applied to “see whether a particular event influences some outcome” [67] and therefore appears most appropriate for investigating the influence of VC funding―being the event?on start-ups’ IP portfolios―being the outcome. More precisely, the number of new patent and trademark applications after VC funding rounds is determined by comparing the stock of patent and trademark applications before and after VC funding rounds. The number of applications before funding rounds is assessed at the point in time 12¹² months prior to the round date. The number of new applications after funding rounds comprises applications filed between the timeframe of 12 months before and 12 months after the round date. Figure 1 exemplarily illustrates the assessment of patent applications for the 12 months’ timeframe.

The final dataset comprises 1062 funding rounds of 531 start-ups with their corresponding patent and trademark portfolios. 35.2% of the observations relate to the first funding round, 36.0%¹³ and 28.8% to round two and three respectively. Furthermore, funding rounds refer to start-ups of the following industries: medical/health (25.0%), computer software and services (19.6%), biotechnology (12.6), communications and

media (11.5%), semiconductors/other elect (11.0%), and other industries (20.3%). The mean value for start-up age at funding is 2.9 years (median: 2.4) implying that most of them are still at early stages of their operations. The results of [18] in a similar study have revealed a higher age at funding (mean: 4.06) which is probably owed to the fact that we only include the first three funding rounds in the analysis. On average, the syndicate per round (number of VCs investing in round) comprises 2.2 investors and has an averaged age (VC age) of nine years as well as undertaken 223 financing deals prior to funding round (VC experience). The mean value for the total amount invested in start-up by VC is USD 9.4 million.

The variable patent dummy ¹⁴ indicates that start-ups already acquire at least one patent prior to first funding in 18.5% of the cases. For instance, also [10] have found that the majority of start-ups do not apply for patents before the entry of VCs. The highest proportion of start-ups that patent prior to first funding is found in the biotechnology industry (23.9%). Previous studies have identified venture-backed start-ups active in this industry as considerably affine to patenting [16] . This appears to be in accordance with the findings of this study when comparing the proportion with other industries. Generally, the proportion is rather low. The mean number of patent applications before round is 8.7 (median: 1). Minimum (0), maximum (303) and standard deviation (24.0) suggest a fairly high variance in start-ups’ patent strategies¹⁵. Interestingly, the computer software and service industry features the highest mean value (12.7). Preceding analyses have suggested that patents for companies of this industry are of little value [16] [43] ―at least before they approach the stage of generating revenues [9] . Firms of this sample, however, might not necessarily have reached this stage yet. The variable new patent applications after round show a slightly lower, but still high level of variance. A mean value of 5.8 and a maximum of 225 patents indicate a pronounced influence of VC funding on subsequent patenting activity. Again, the results are contrary to previous findings regarding the importance of patenting in the software industry. The underlying data suggest a high maximum (171) and considerable great mean (6.7) for the number of new patent applications after funding round in this industry.

In contrast, trademarking activity appears to be more homogenous among the investigated start-ups. Generally, mean (1.8), minimum (0), maximum (28) and standard deviation (3.2) of trademark applications before round show lower values implying that the distribution of trademarks before funding is less dispersed compared to patents. For instance, [21] have also found start-ups’ trademarking strategies being less diverse than patenting strategies. Start-ups operating in the communication and media industry demonstrate the highest mean value for this variable (2.6) as well as for new trademark applications after round (4.9) which appears natural to assume considering previous analyses. Reference [11] has aimed at answering a slightly different research question, but nevertheless their results have proven the high relevance of trademarks in this industry. The values for new trademark applications after round across all industries (mean: 3.3, median: 2, min: 0; max: 84, standard deviation: 5.9) also characterize trademarking activity as less distorted. Besides, extant literature has suggested that trademarks are more widely applicable than patents (e.g. [35] [43] [38] ). However, the results of this study suppose that patents are more important. Mean values for both applications before and new applications after round are higher in the case of patents. Furthermore, the variable trademark dummy reports that only 10.0% of start-ups obtain trademarks before first funding which does not lend support for the assumption that trademarks are more deployable than patents. An overview of descriptive results can be found in Table 2 and Table 3.

Notes: N = 1062 observations of 531 start-ups that received VC funding between 1991 and 2009. Data sources: VC data from VentureXpert, patent data from PATSTAT, trademark data from USPTO.

The results of the multivariate analysis for M1 and M2 are first tested using a t-test before further verified through OLS regression. Table 4 summarizes the results of the t-test. The mean value for the number of new patent applications after round for first funding rounds is 6.3. Regarding hypothesis 1, the t-test shows that the null hypothesis―first funding rounds do not have a significant effect on the number of new patent applications―can be rejected (p < 0.001). Likewise, the results deliver strong support for hypothesis 2 which assumes a rise in the number of trademarks after first funding

Notes: N = 1062 observations of 531 start-ups that received VC funding between 1991 and 2009; Data sources: VC data from VentureXpert, patent data from PATSTAT, trademark data from USPTO; *p < 0.05, **p < 0.01, ***p < 0.001; ^aNew patents and new trademarks refer to new patent and trademark applications.

rounds. The mean value the new trademark applications after round for first rounds is 2.8 and statistically significant (p < 0.001). Since the mean for the number of new applications is considerably higher for patents (6.3) than for trademarks (2.8) it can be assumed that hypothesis 3 does not hold. The performed comparison of the two means confirms this assumption and suggests that rather the opposite is the case. Furthermore, t-tests are applied to investigate the impact of VC funding on additional patent (H4) and trademark applications (H5) along the venture cycle. The mean values for new patent applications after round are 6.3 for first, 5.8 for second and 5.4 for third rounds. This may appear as support for a decreasing number of new patent applications with the start-up’s progress along the venture cycle (H4). However, the results of the t-test do not allow rejecting the null hypothesis in both cases and therefore do not provide support for hypothesis 4. The findings for hypothesis 5 are mixed. The number of new trademark applications after round shows mean values of 2.8, 3.7 and 3.3 for first, second and third rounds respectively. Regarding the comparison between first and second rounds the null hypothesis can be rejected (p < 0.05). However, the results do not suggest a significantly higher effect of third rounds on trademarking activity compared to second rounds. Taken together, hypothesis 5 is only partly supported, meaning that the number of additional trademarks filed rises from first to second rounds, but not from second two third rounds.

The results of the t-test are further investigated in an OLS regression. In order to compensate for the skewed distributions of the dependent variables―new patent applications after round and new trademark applications after round―the natural logs of these variables are used instead. The following equation estimates the number of new patent applications after round for firm i in round t.¹⁶

Table 5 summarizes the results for the 12 months’ timeframe (M1 and M2). In the underlying regression, first rounds are used as reference group. This implicates that the effect of second and third rounds is estimated relative to the effect of first rounds. More specifically, this means that the constant of the regression estimates the effect of first rounds, whereas the effect of second and third rounds is the sum of the constant’s value and the coefficient of the round 2 dummy or the round 3 dummy, respectively. The reported results of M1 suggest a strong influence of first funding rounds on subsequent patenting activity, with an increase of 80.5% of the patent portfolio (p < 0.001). Hypothesis 1 is thus confirmed. When including the patent dummy for first funding rounds, the estimated effect decreases. This implies that start-ups that already had acquired at least one patent prior to first funding only feature an increase of 48,6% in their patent portfolio (p < 0.01). This may indicate that the influence of VC funding is smaller for start-ups that already had recognized themselves the need for protecting their technological knowledge prior to first funding.

M2 investigates the effect of first funding on consecutive trademarking activity and delivers strong support for hypothesis 2. The value of the constant estimates an increase in start-ups’ trademark portfolios of 71.1% after first rounds (p < 0.001). Contrary to the case of patents, the trademark dummy does not show a significant impact which indicates that whether having or not at least one trademark prior to first funding is largely irrelevant for subsequent trademarking.

When comparing the values of the constants in M1 and M2, support for hypothesis 3 (p < 0.001) cannot be found. As above mentioned, the relative growth from first rounds for patents is 80.5%, whereas 71.1% for trademarks. Thus, a higher effect for trademarking activity cannot be detected which is also in accordance with the previously

Notes: p-values in parentheses. Reference round number: “round 1”; reference industry: “Medical/health”; reference region: “N. California”. Data sources: VC data from VentureXpert, patent data from PATSTAT, trademark data from USPTO. ^aNew patents and new trademarks refer to new patent and trademark applications. *p < 0.05, **p < 0.01, ***p < 0.001.

performed t-test.

Furthermore, we expect a decreasing number of new patent applications after funding with the progress along the venture cycle. The estimated effects for second and third rounds are not significant on the 95% confidence level. This means, the growth of the patent portfolio after second and third rounds does not differ from the effect resulting from first rounds. In other words, the relative growth will be 80.5% in all three cases. Consequently, there exists no decreasing effect of patenting activity along the venture cycle and hypothesis 4 is rejected.

Finally, M2 is used to test hypothesis 5 which assumes a rise in the number of additional trademark filings with each subsequent funding round. The relative growth of the trademark portfolio after first rounds is 71.1% (p < 0.001). The coefficient of the round 2 dummy suggests that the growth of the portfolio is 21.2% (p < 0.01) higher compared to first rounds and thus, a cumulative growth by 92.3% (71.1% plus 21.2%) after second rounds is estimated. This seems to lend tentative support for hypothesis 5. However, when examining the effect of third rounds, we cannot presume a significant effect. This means the portfolio grows by 71.1% after third rounds which are not higher than the effect of second rounds. Although, the results for second rounds are in favor of hypothesis 5, it eventually has to be rejected due to the non-existent additional effect of third rounds. These findings have already been predicted by the t-test.

Interestingly, the effect of start-up age is not significant in both models. This may imply that the influence of VCs on subsequent IP activity is dependent on the stage of the start-up within the venture cycle?which is approximated by the number of funding rounds (see also [9] )―rather than on the actual age. For M2, the results report a significant effect of the total amount invested by VC in a start-up (p < 0.01). However, with a coefficient indicating an additional growth of 1% resulting from one additional million USD invested this effect seems negligible. The findings for the number of investors are similar. An additive growth of 4.3% (p < 0.05) caused by one additional investor is rather small and also only exists in M2. Additionally, a differing impact due to VC age and experience is not observable in both models.