Milk on Ice: Antarctic time capsule of whole milk powder sheds light on the enduring qualities—and evolution—of dairy products past and present

A new Journal of Dairy Science® comparative study demonstrates that the milk powder fueling our ancestors is remarkably similar to the milk powder we enjoy today

Philadelphia, March 12, 2024 In a remarkable discovery, whole milk powder manufactured in New Zealand in 1907 and transported to Antarctica with explorers seeking the South Pole was unveiled after more than a century. The find has allowed dairy researchers to answer the question: Is the milk we enjoy today different from the milk consumed in previous generations? Out now in the Journal of Dairy Science, a new comparative study has peered back in time to demonstrate that—despite advancements in selective breeding and changes to farm practices—milk of the past and milk today share more similarities than differences, and are still crucial building blocks of human nutrition.

On New Year’s Day in 1908, explorer Ernest Shackleton’s British Antarctic Expedition aboard the ship Nimrod set sail from Lyttelton, New Zealand, on a quest to be the first to set foot on the South Pole. While the wharf was packed with well-wishers, the ship was packed with dairy: 1,000 pounds of dried whole milk powder, 192 pounds of butter, and 2 cases of cheese. Shackleton and his crew would make it farther south than anyone before them—within 100 nautical miles of the pole—and leave behind their base camp.  

A century later, one remaining container of Defiance brand whole milk powder was discovered during the Antarctic Heritage Trust restoration project, having been frozen for the past 100 years.

Lead investigator Skelte Anema, DPhil, principal research scientist with Fonterra Research and Development Centre in Palmerston North, New Zealand, explained the discovery’s significance: “The Shackleton dried milk is possibly the best-preserved sample manufactured during the pioneering years of commercial milk powder production, and its discovery gives us a once-in-a-lifetime chance to understand the similarities and differences between a roller-dried milk powder manufactured over 100 years ago with modern spray-dried counterparts.”

Anema noted, “Before we had vacuum-assisted evaporation, milk powders in the early twentieth century were manufactured by a roller-drying process involving boiling-hot milk being poured between two steam-heated revolving cylinders so that the water evaporated, leaving a thin sheet of dried milk that would have been milled and sieved.” We know these early milk powders weren’t as sophisticated as they are today, but what other differences existed?

With the help of the Antarctic Heritage Trust, Anema and an interdisciplinary team of scientists with the Fonterra Research and Development Centre were able to study a few hundred grams of Defiance milk, and set out to compare it with two modern-day commercial, noninstantized spray-dried whole milk powder samples from Fonterra. Their analysis involved comparing the major component composition, major and trace mineral composition, protein composition, fatty acid composition, phospholipid composition microstructural properties, color analysis, and volatile component analysis of the different whole milk powder samples.


Caption: The photo on the top left (A) shows the tin-plated can of Defiance brand dried milk found in Shackleton’s Cape Royds base camp hut, with a close-up label in the bottom photo (C) (courtesy of the Antarctic Heritage Trust, Christchurch, New Zealand). The top-right photo (B) is of the Joseph Nathan & Sons Bunnythorpe Defiance Dried Milk Factory circa 1904 (courtesy of Massey University, Palmerston North, New Zealand).

The results proved surprising and contrary to claims of changes in milk over time. “Despite more than a century between the samples, the composition of bulk components and detailed protein, fat, and minor components has not changed drastically in the intervening years,” said Anema. The fatty acid composition, phospholipid composition, and protein composition, including casein and whey protein genetic variations, were, in general, remarkably similar.

The major mineral components were also alike between samples, except for high levels of lead, tin, iron, and other trace minerals found in the Shackleton whole milk powder—likely from the tin-plated can it was stored in and the equipment and water supply of the day. “These issues have been essentially eliminated from modern milk powders through the use of stainless steel and quality water services,” said Anema.

Another notable difference was the presence of oxidation-related volatile aroma compounds in the Shackleton samples, “perhaps from less-than-ideal collection and storage of the raw milk before drying,” said Anema, “but it’s much more likely that—even in frozen conditions—being stored in an open tin for a century is going to result in continued oxidation.”

Despite the remarkable similarities, the team was eager to point out that the modern spray-dried whole milk powders were substantially superior in terms of the powder quality—particularly regarding appearance and their ability to be easily dissolved in water.

Overall, this Antarctic time capsule provides a rare and important glimpse into the evolution of dairy food production and highlights the improvements the dairy sector has made as well as its enduring influence. “The Shackleton samples are a testament to the importance of dairy products—which are rich in protein and energy as well as flexible enough to be powdered for easy transport, preparation, and consumption,” noted Anema.

Whether at the turn of the twentieth century or today, these results underscore the fact that dairy products serve as an essential foundation for human nutrition—fueling our discoveries past and present.

Notes for editors
The article is ““Milk on Ice”: A detailed analysis of Ernest Shackleton's century-old whole milk powder in comparison with modern counterparts,” by Justin G. Bendall, Abraham S. Chawanji, Bertram Y. Fong, Paul Andrewes, Lin Ma, Alastair K. H. MacGibbon, and Skelte G. Anema (https://doi.org/10.3168/jds.2023-23893). It appears in the Journal of Dairy Science, volume 107, issue 3 (March 2024), published by the American Dairy Science Association and Elsevier.

The article is openly available at https://www.journalofdairyscience.org/article/S0022-0302(24)00507-1/fulltext and the PDF version is available at https://www.journalofdairyscience.org/action/showPdf? pii=S0022-0302%2824%2900507-1.

Full text of this article is also available to credentialed journalists upon request; contact Eileen Leahy at +1 732 406 1313 or jdsmedia@elsevier.com. Journalists wishing to interview the authors should contact the corresponding author, Skelte Anema, DPhil, Principal Research Scientist with Fonterra Research and Development Centre in Palmerston North, New Zealand at skelte.anema@fonterra.com.

About the Journal of Dairy Science
The Journal of Dairy Science® (JDS), an official journal of the American Dairy Science Association® (ADSA), is co-published by Elsevier and ADSA. It is the leading general dairy research journal in the world. JDS readers represent education, industry, and government agencies in more than 70 countries, with interests in biochemistry, breeding, economics, engineering, environment, food science, genetics, microbiology, nutrition, pathology, physiology, processing, public health, quality assurance, and sanitation. JDS has a 2022 Journal Impact Factor of 3.5 and five-year Journal Impact Factor of 4.2 according to Journal Citation Reports™ (Source: Clarivate™ 2023).www.journalofdairyscience.org

About the American Dairy Science Association (ADSA®)
The American Dairy Science Association (ADSA) is an international organization of educators, scientists, and industry representatives who are committed to advancing the dairy industry and keenly aware of the vital role the dairy sciences play in fulfilling the economic, nutritive, and health requirements of the world’s population. It provides leadership in scientific and technical support to sustain and grow the global dairy industry through generation, dissemination, and exchange of information and services. Together, ADSA members have discovered new methods and technologies that have revolutionized the dairy industry.www.adsa.org

About Elsevier
As a global leader in information and analytics, Elsevier helps researchers and healthcare professionals advance science and improve health outcomes for the benefit of society. We do this by facilitating insights and critical decision-making with innovative solutions based on trusted, evidence-based content, and advanced AI-enabled digital technologies.

We have supported the work of our research and healthcare communities for more than 140 years. Our 9,500 employees around the world, including 2,500 technologists, are dedicated to supporting researchers, librarians, academic leaders, funders, governments, R&D-intensive companies, doctors, nurses, future healthcare professionals, and educators in their critical work. Our 2,900 scientific journals and iconic reference books include the foremost titles in their fields, including Cell Press, The Lancet and Gray’s Anatomy.

Together with the Elsevier Foundation, we work in partnership with the communities we serve to advance inclusion and diversity in science, research, and healthcare in developing countries and around the world.

Elsevier is part of RELX, a global provider of information-based analytics and decision tools for professional and business customers. For more information on our work, digital solutions, and content, visit www.elsevier.com.